http://www.physicsbook.gatech.edu/api.php?action=feedcontributions&feedformat=atom&user=Rwilliams354Physics Book - User contributions [en]2026-04-28T15:35:35ZUser contributionsMediaWiki 1.42.7http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24949Conductivity2016-11-27T19:56:55Z<p>Rwilliams354: /* Equations */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Conductors, Semiconductors, and Insulators are the main three classifications of a material when talking about its electrical conductivity. Conductors are materials with high conductivity. Semiconductors have an in between level of conductivity, while insulators have low conductivity. Meaning if you want to pass a lot of electricity to something use a conductor, if you want to pass some electricity but also lower the original amount use a semiconductor, and if you want to cut the flow of electricity use an insulator. Provided below is a list of materials that fit into each category.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:53, 27 November 2016 (EST)<br />
<br />
Conductors: Gold, Iron, Silver, Copper, Aluminum, Tin<br />
Semiconductors: Silicon, Germanium<br />
Insulators: Glass, Porcelain, Rubber, Cloth, Paper, Air<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
<br />
===Further reading===<br />
<br />
Georgia Tech Research and Information regarding conduction in School of Materials Science and Engineering <br />
http://www.mse.gatech.edu/research/equipment-facilities/electrical-properties-materials-and-devices--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:55, 27 November 2016 (EST)<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
==References==<br />
<br />
<br />
<br />
'''History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24947Conductivity2016-11-27T19:56:04Z<p>Rwilliams354: /* See also */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Conductors, Semiconductors, and Insulators are the main three classifications of a material when talking about its electrical conductivity. Conductors are materials with high conductivity. Semiconductors have an in between level of conductivity, while insulators have low conductivity. Meaning if you want to pass a lot of electricity to something use a conductor, if you want to pass some electricity but also lower the original amount use a semiconductor, and if you want to cut the flow of electricity use an insulator. Provided below is a list of materials that fit into each category.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:53, 27 November 2016 (EST)<br />
<br />
Conductors: Gold, Iron, Silver, Copper, Aluminum, Tin<br />
Semiconductors: Silicon, Germanium<br />
Insulators: Glass, Porcelain, Rubber, Cloth, Paper, Air<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
<br />
===Further reading===<br />
<br />
Georgia Tech Research and Information regarding conduction in School of Materials Science and Engineering <br />
http://www.mse.gatech.edu/research/equipment-facilities/electrical-properties-materials-and-devices--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:55, 27 November 2016 (EST)<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
==References==<br />
<br />
<br />
<br />
'''History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24944Conductivity2016-11-27T19:55:47Z<p>Rwilliams354: /* Further reading */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Conductors, Semiconductors, and Insulators are the main three classifications of a material when talking about its electrical conductivity. Conductors are materials with high conductivity. Semiconductors have an in between level of conductivity, while insulators have low conductivity. Meaning if you want to pass a lot of electricity to something use a conductor, if you want to pass some electricity but also lower the original amount use a semiconductor, and if you want to cut the flow of electricity use an insulator. Provided below is a list of materials that fit into each category.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:53, 27 November 2016 (EST)<br />
<br />
Conductors: Gold, Iron, Silver, Copper, Aluminum, Tin<br />
Semiconductors: Silicon, Germanium<br />
Insulators: Glass, Porcelain, Rubber, Cloth, Paper, Air<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Georgia Tech Research and Information regarding conduction in School of Materials Science and Engineering <br />
http://www.mse.gatech.edu/research/equipment-facilities/electrical-properties-materials-and-devices--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:55, 27 November 2016 (EST)<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
<br />
<br />
'''History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24940Conductivity2016-11-27T19:53:13Z<p>Rwilliams354: /* Classification of Materials by Conductivity */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Conductors, Semiconductors, and Insulators are the main three classifications of a material when talking about its electrical conductivity. Conductors are materials with high conductivity. Semiconductors have an in between level of conductivity, while insulators have low conductivity. Meaning if you want to pass a lot of electricity to something use a conductor, if you want to pass some electricity but also lower the original amount use a semiconductor, and if you want to cut the flow of electricity use an insulator. Provided below is a list of materials that fit into each category.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:53, 27 November 2016 (EST)<br />
<br />
Conductors: Gold, Iron, Silver, Copper, Aluminum, Tin<br />
Semiconductors: Silicon, Germanium<br />
Insulators: Glass, Porcelain, Rubber, Cloth, Paper, Air<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
<br />
<br />
'''History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24936Conductivity2016-11-27T19:52:46Z<p>Rwilliams354: /* Classification of Materials by Conductivity */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Conductors, Semiconductors, and Insulators are the main three classifications of a material when talking about its electrical conductivity. Conductors are materials with high conductivity. Semiconductors have an in between level of conductivity, while insulators have low conductivity. Meaning if you want to pass a lot of electricity to something use a conductor, if you want to pass some electricity but also lower the original amount use a semiconductor, and if you want to cut the flow of electricity use an insulator. Provided below is a list of materials that fit into each category.<br />
<br />
Conductors: Gold, Iron, Silver, Copper, Aluminum, Tin<br />
Semiconductors: Silicon and Germanium<br />
Insulators: Glass, Porcelain, Rubber, Cloth, Paper, Air<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
<br />
<br />
'''History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24896Conductivity2016-11-27T19:20:21Z<p>Rwilliams354: /* History(New) */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
<br />
<br />
'''History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24893Conductivity2016-11-27T19:15:04Z<p>Rwilliams354: /* History(New) */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:15, 27 November 2016 (EST)<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
<br />
<br />
'''History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24890Conductivity2016-11-27T19:14:27Z<p>Rwilliams354: /* References */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
<br />
<br />
'''History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24889Conductivity2016-11-27T19:14:13Z<p>Rwilliams354: /* References */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
History''': "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
'''Equations''': "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24888Conductivity2016-11-27T19:13:39Z<p>Rwilliams354: /* Equations */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J=(conductivity)E--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
Equations: "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24886Conductivity2016-11-27T19:13:21Z<p>Rwilliams354: /* Conductivity in Real Life */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''<br />
<br />
J=(conductivity)E<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. <br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
Equations: "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24884Conductivity2016-11-27T19:13:05Z<p>Rwilliams354: /* References */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''<br />
<br />
J=(conductivity)E<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. <br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''--[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:13, 27 November 2016 (EST)<br />
<br />
Equations: "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24878Conductivity2016-11-27T19:10:39Z<p>Rwilliams354: /* References */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''<br />
<br />
J=(conductivity)E<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. <br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''<br />
<br />
Equations: "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php --[[User:Rwilliams354|Rwilliams354]] ([[User talk:Rwilliams354|talk]]) 14:10, 27 November 2016 (EST)</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24877Conductivity2016-11-27T19:10:06Z<p>Rwilliams354: /* References */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''<br />
<br />
J=(conductivity)E<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. <br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''<br />
<br />
Equations: "Conductivity." Maxwells-Equations.com, 2012. http://maxwells-equations.com/materials/conductivity.php</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24868Conductivity2016-11-27T18:56:51Z<p>Rwilliams354: /* Equations */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
'''Maxwell's Equation for Electric Conductivity''''''<br />
<br />
J=(conductivity)E<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. <br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24867Conductivity2016-11-27T18:56:37Z<p>Rwilliams354: /* Equations */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
'''<br />
Maxwell's Equation for Electric Conductivity'''<br />
<br />
J=(conductivity)E<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. <br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24866Conductivity2016-11-27T18:56:18Z<p>Rwilliams354: /* Equations */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
Maxwell's Equation for Electric Conductivity<br />
<br />
J=(conductivity)E<br />
<br />
J= Electric Current Density<br />
E= Electric Field<br />
<br />
Electric current density can be thought of as the electric current per cross sectional area of a specific material. Therefore this formula relates to each material differently. Every material has a specific conductivity associated with it, and this conductivity can help describe the electric field in each material. For example, materials such as copper and silver have extremely high electric conductivity and therefore in order to not have an almost infinite electric current density we can approximate the electric field inside the metals to be zero. This equation is essentially the proof for all metals having a zero electric field on the inside. <br />
<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24814Conductivity2016-11-27T16:56:01Z<p>Rwilliams354: </p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
Maxwell's Equation for Conductivity<br />
<br />
J=(conductivity)E<br />
<br />
J= Electric Current Density<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24180Conductivity2016-11-26T00:48:34Z<p>Rwilliams354: /* Conductivity in Real Life */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
https://www.youtube.com/watch?v=ODbgKXFED5o<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24157Conductivity2016-11-25T23:56:49Z<p>Rwilliams354: /* History */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
==History(New)==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24154Conductivity2016-11-25T23:56:20Z<p>Rwilliams354: /* History */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction'''<br />
<br />
''Born 1666 in Canterbury, England.''<br />
''Died 1736 in London, England.''<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24153Conductivity2016-11-25T23:55:29Z<p>Rwilliams354: /* History */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction<br />
<br />
''Born 1666 in Canterbury, England<br />
Died 1736 in London, England<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.'''''<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24144Conductivity2016-11-25T23:45:22Z<p>Rwilliams354: /* History */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
==History==<br />
'''Stephen Gray, Father of Conduction<br />
<br />
Born 1666 in Canterbury, England<br />
Died 1736 in London, England<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.'''<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24143Conductivity2016-11-25T23:45:09Z<p>Rwilliams354: /* References */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
==History==<br />
Stephen Gray, Father of Conduction<br />
<br />
Born 1666 in Canterbury, England<br />
Died 1736 in London, England<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
'''History: "Gray, Stephen." Complete Dictionary of Scientific Biography. . Encyclopedia.com. 25 Nov. 2016 <http://www.encyclopedia.com>.'''</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24133Conductivity2016-11-25T23:28:13Z<p>Rwilliams354: /* History */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
==History==<br />
Stephen Gray, Father of Conduction<br />
<br />
Born 1666 in Canterbury, England<br />
Died 1736 in London, England<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said discovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=24132Conductivity2016-11-25T23:27:56Z<p>Rwilliams354: /* History */</p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
==History==<br />
Stephen Gray, Father of Conduction<br />
<br />
Born 1666 in Cantebury, England<br />
Died 1736 in London, England<br />
<br />
Gray was an innovative thinker who performed many a experiment including work with the transmission of electricity. One day while performing one of his experiments, unbeknownst to him he discovered the difference between insulators and conductors. He was working with transmitting electricity and he changed the transmission wire from silk to brass wire when he noticed that electricity passes completely different in brass than it does in silk. After said disocovery, Gray spend the next 3 years with the help of friends and family doing more research in similar topics, and with this research some might say solidified his name as the father of conduction.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Conductivity&diff=23579Conductivity2016-11-15T21:56:40Z<p>Rwilliams354: </p>
<hr />
<div><br />
<br />
'''<br />
''<br />
Claimed by myoung65, Spring 2016<br />
<br />
Claimed by Reed Williams Fall 2016<br />
<br />
'''<br />
==Definition==<br />
<br />
Electrical Resistivity is a measure of how a given material opposes current flow. Low resistivity shows a material that allows the flow of current, whereas the opposite is true for high resistivity.<br />
Electrical Conductivity is the reciprocal/inverse of Electrical Resistivity, in that it measures the ability of a given material to conduct electric current<br />
<br />
==Symbols==<br />
<br />
Electrical Resistivity is mainly represented by the Greek lower-case rho. <br />
Electrical Conductivity is mainly represented by the Greek lower-case sigma, but is occasionally represented by a lower-case kappa, or gamma.<br />
<br />
== SI Units ==<br />
<br />
Electrical Resistivity is measured in Ohm-Metres.<br />
Electrical Conductivity is measured in Siemens per Metre<br />
<br />
== Classification of Materials by Conductivity ==<br />
<br />
Materials with high Conductivity are known as conductors. ex. metals<br />
Materials with low Conductivity are known as resistors. ex. vacuums, glass, etc.<br />
<br />
== Semiconductors ==<br />
<br />
Semiconductors are materials that have a conductivity in-between that of an insulator and a conductor. However, as temperature increases, unlike in most metals, the conductivity of semiconductors increases.<br />
<br />
== Temperature Dependence ==<br />
<br />
As temperature increases, the electrical resistivity of metals increases. This is a reason why when computers heat up, they tend to slow down. Some materials exhibit superconductivity at extremely low temperatures. Below a certain temperature, resistivity vanishes, such as Pb at 7.20 K.<br />
<br />
==Equations==<br />
<br />
'''Poulliet's Law'''<br />
<br />
R=ρℓ/A<br />
<br />
R = Electric Resistance<br />
ρ = Electric Resistivity<br />
ℓ = Length<br />
A = Cross-Sectional Area<br />
<br />
Poulliet's Law states that a given materials resistance will increase in length, while it will decrease with an increase in Area.<br />
<br />
==Conductivity in Real Life==<br />
<br />
Conductors are used to carry electricity, as well as electrical signals in circuits. <br />
Complementary metal–oxide–semiconductors, or CMOS for short, are the foundational building block of gate based logic circuits, that make up the majority of all modern electronics. CMOS circuits are composed of a combination of p-type and n-type semiconductors. These semiconductors will change their conductivity, based on the applied voltage, allowing for logic of 0's and 1's, or low voltage and high voltage, to be transferred through logical circuits. This allows us to apply boolean logic to circuits, such as AND and OR logic, or even create an amalgamation of AND's and OR's to create electronics, such as multiplexors, switches, latches, registers, decoders, encoders, etc.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]<br />
<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page. Reeds Page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Gauss%27s_Law&diff=23578Gauss's Law2016-11-15T21:55:03Z<p>Rwilliams354: </p>
<hr />
<div>'''Claimed by Kel Johnson'''<br />
<br />
<br />
One of Maxwell's Equations, formulated by Carl Friedrich Gauss. Gauss's Law is useful in determining the relationship between electric charge and the surrounding field caused by the charge. <br />
<br />
==The Main Idea==<br />
<br />
The idea of Gauss's Law is that the electric flux out of a closed surface is equivalent to the charge enclosed, divided by the permittivity. There is a near identical law to this law, known as Gauss's law for Magnetism. The variation found is that magnetic fields are used instead of electric fields in the calculations. Also, Gauss's Law for Gravity is very similar as well. To state it again, the electric flux passing through a closed surface is the same as the charge enclosed, divided by permittivity of the surface. This implies that the electric flux is proportional to the total charge enclosed. Any closed surface can be have Gauss's Law applied to it. For symmetrically shaped objects, Gauss's Law greatly simplifies calculation of electric field enclosed by surface. <br />
<br />
<br />
===A Mathematical Model===<br />
<br />
A very helpful and clear summary of this Law can be found in the diagram below. As can be seen on the left side of this diagram, change in flux equals electric field multiplied by change in area. <br />
<br />
[[File:Gaulaw.gif]]<br />
<br />
<br />
To more clearly state it, the formula for this Law is the electric flux equals the total charge contained by a closed surface, divided by the permittivity (epsilon zero). <br />
<br />
[[File:Adc2dff3156800a39ef0a9df76a7d868.png]]<br />
<br />
<br />
==Examples==<br />
<br />
In order to apply Gauss's Law, it is important to be certain you are working with a closed surface, then set electric flux equal to the internal field divided by the permittivity (epsilon not). An example of this Law being applied can be found below. <br />
<br />
[[File:Gauss_law3.png]]<br />
<br />
Below is a further example of Gauss's Law with explanation.<br />
<br />
[[File:Gauss_14.jpg]]<br />
<br />
==Connectedness==<br />
Gauss's Law, as well as the other Maxwell Equations form a basis for electrodynamics. They are the fundamental core of this field of study. <br />
Magnetostatics study is also closely related to Gauss' Law, but in particular Gauss's Law of Magnetism, which is very similar to Gauss's Law relating to electric fields. <br />
<br />
==History==<br />
<br />
[[File:220px-Carl_Friedrich_Gauss_(C._A._Jensen).jpg]]<br />
<br />
Carl Friedrich Gauss was a German Mathematician and Physicist who contributed notably to a wide variety of fields regarding mathematical and scientific study. He has been referred to as the "greatest mathematician since antiquity" and the "foremost of mathematicians". He is considered one of the most impactful and influential contributors to the fields of Mathematics and Physics in history.<br />
<br />
== See also ==<br />
<br />
Gauss's Law is tied in closely with the other of Maxwell's equations that can be found here in the Physics Book.<br />
<br />
http://physicsbook.gatech.edu/Gauss%27s_Flux_Theorem<br />
<br />
http://physicsbook.gatech.edu/Faraday%27s_Law<br />
<br />
http://physicsbook.gatech.edu/Magnetic_Flux<br />
<br />
http://physicsbook.gatech.edu/Ampere%27s_Law<br />
<br />
<br />
===External links===<br />
<br />
http://physics.info/law-gauss/<br />
<br />
https://en.wikipedia.org/wiki/Gauss%27s_law<br />
<br />
https://en.wikipedia.org/wiki/Carl_Friedrich_Gauss<br />
<br />
==References==<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/electric/gaulaw.html<br />
<br />
spiff.rit.edu<br />
<br />
study.com<br />
<br />
<br />
[[Category:Which Category did you place this in?]]</div>Rwilliams354http://www.physicsbook.gatech.edu/index.php?title=Gauss%27s_Law&diff=23577Gauss's Law2016-11-15T21:52:59Z<p>Rwilliams354: </p>
<hr />
<div>'''Claimed by Kel Johnson'''<br />
"Claimed by Reed Williams for Fall 2016"<br />
<br />
One of Maxwell's Equations, formulated by Carl Friedrich Gauss. Gauss's Law is useful in determining the relationship between electric charge and the surrounding field caused by the charge. <br />
<br />
==The Main Idea==<br />
<br />
The idea of Gauss's Law is that the electric flux out of a closed surface is equivalent to the charge enclosed, divided by the permittivity. There is a near identical law to this law, known as Gauss's law for Magnetism. The variation found is that magnetic fields are used instead of electric fields in the calculations. Also, Gauss's Law for Gravity is very similar as well. To state it again, the electric flux passing through a closed surface is the same as the charge enclosed, divided by permittivity of the surface. This implies that the electric flux is proportional to the total charge enclosed. Any closed surface can be have Gauss's Law applied to it. For symmetrically shaped objects, Gauss's Law greatly simplifies calculation of electric field enclosed by surface. <br />
<br />
<br />
===A Mathematical Model===<br />
<br />
A very helpful and clear summary of this Law can be found in the diagram below. As can be seen on the left side of this diagram, change in flux equals electric field multiplied by change in area. <br />
<br />
[[File:Gaulaw.gif]]<br />
<br />
<br />
To more clearly state it, the formula for this Law is the electric flux equals the total charge contained by a closed surface, divided by the permittivity (epsilon zero). <br />
<br />
[[File:Adc2dff3156800a39ef0a9df76a7d868.png]]<br />
<br />
<br />
==Examples==<br />
<br />
In order to apply Gauss's Law, it is important to be certain you are working with a closed surface, then set electric flux equal to the internal field divided by the permittivity (epsilon not). An example of this Law being applied can be found below. <br />
<br />
[[File:Gauss_law3.png]]<br />
<br />
Below is a further example of Gauss's Law with explanation.<br />
<br />
[[File:Gauss_14.jpg]]<br />
<br />
==Connectedness==<br />
Gauss's Law, as well as the other Maxwell Equations form a basis for electrodynamics. They are the fundamental core of this field of study. <br />
Magnetostatics study is also closely related to Gauss' Law, but in particular Gauss's Law of Magnetism, which is very similar to Gauss's Law relating to electric fields. <br />
<br />
==History==<br />
<br />
[[File:220px-Carl_Friedrich_Gauss_(C._A._Jensen).jpg]]<br />
<br />
Carl Friedrich Gauss was a German Mathematician and Physicist who contributed notably to a wide variety of fields regarding mathematical and scientific study. He has been referred to as the "greatest mathematician since antiquity" and the "foremost of mathematicians". He is considered one of the most impactful and influential contributors to the fields of Mathematics and Physics in history.<br />
<br />
== See also ==<br />
<br />
Gauss's Law is tied in closely with the other of Maxwell's equations that can be found here in the Physics Book.<br />
<br />
http://physicsbook.gatech.edu/Gauss%27s_Flux_Theorem<br />
<br />
http://physicsbook.gatech.edu/Faraday%27s_Law<br />
<br />
http://physicsbook.gatech.edu/Magnetic_Flux<br />
<br />
http://physicsbook.gatech.edu/Ampere%27s_Law<br />
<br />
<br />
===External links===<br />
<br />
http://physics.info/law-gauss/<br />
<br />
https://en.wikipedia.org/wiki/Gauss%27s_law<br />
<br />
https://en.wikipedia.org/wiki/Carl_Friedrich_Gauss<br />
<br />
==References==<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/electric/gaulaw.html<br />
<br />
spiff.rit.edu<br />
<br />
study.com<br />
<br />
<br />
[[Category:Which Category did you place this in?]]</div>Rwilliams354