Electric Potential: Difference between revisions

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'''AUTHOR:  
'''AUTHOR: Rmohammed7'''
CLAIMED BY HAYOUNG KIM (SPRING 2016)'''
'''REVISED BY: HAYOUNG KIM (SPRING 2016)'''


This page discusses the Electric Potential and examples of how it is used.
This page discusses the Electric Potential and examples of how it is used.
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== The Main Idea ==
== The Main Idea ==


Electric Potential is the potential energy associated with interacting charged particles that create electric fields and impact each other through these fields. Electric potential is found by travleing across a path through a uniform or nonuniform electric field.
Electric potential is a rather difficult concept as it is usually accompanied by other topics. For example, electric potential is not the same as electric potential energy as electric potential is defined as the total potential energy per charge and is basically used to describe the electric field's effect at a certain location. In other words, electric potential is purely dependent on the electric field (whether it is uniform or nonuniform) and the location, whereas the electric potential energy also depends on the amount of charge the object in the system is experiencing. Also, although electric potential is an important topic to learn, most problems encountered will not ask to find just the "electric potential," instead, questions will most likely ask for the "electric potential difference." This is because electric potential is measured using different locations, or more specifically pathways between the different locations, so instead of determining the electric potential of location A and the electric potential of final location B, it would make more sense to determine the "difference in electric potential between locations A and B."
Potential energy can be thought of as the energy that is stored within a system that will soon be utilized for some other action. It is the opposite of kinetic energy, which is the energy associated with something in motion. For studying electric potential of charged particles, we first need to understand that sigle particles themselves dont really have potential energy. When we analyze a system for electric potential, we need to choose a a system containing one or more objects/particle/etc.. The potential energy will be derived from the interactions between the objects within our system. On the other hand, kineic energy will be related to the work done by the surroundings of the system.This value can be changed if the work done is positive or negative. Therefore, the change in kineic energy of our system must be equal to the work done by the surroundings. Work can be derived by calculating the dot product of the force and displacement. Potential energy is asscociated with the internal work of the system, that is, work that is done by objects counted within the system. Therefore, the potential energy change of a system is equal to the negative interior work. Now, to put all this together, we have the conservation of energy rule. This states that energy cannot be created or destroyed between events of interacting objects. That is why delta K plus delta U must be zero.


==The Main Idea==
===A Mathematical Model===


When calculating the changes in potential energy of a system, it would be useful to find a quantity that is unique from the charge of out particle. After finding this variable, we can multiply it by the charge to get or delta U. Regardelss of whether our particle is a proton or electron, our change in potential energy formula boils down to ''(some charge)*(-Ex*deltaX)''. The part that is the same in both cases is the Ex times deltaX. This is called the difference of electric potential between 2 locations. This value is usually notated as DeltaV, with units of volts.  
Like mentioned in the Main Idea, instead of electric potential, in most cases, electric potential difference is needed to be found. The general equation for the potential difference is <math>∆{{U}_{electric}} = {q} * ∆{V} </math>.


===A Mathematical Model===
'''<math>∆{{U}_{electric}}</math>''' is the electric potential energy, which is measured in Joules (J). '''q''' is the charge of the particle moving through the path of the electric potential difference, which is measured in coulombs (C). '''∆V''' is the electric potential difference, which is measured in Joules per Coulomb (J/C), or just Volts (V).


Finding Potential Differences in Uniform Fields.
Aside from the general equation, the electric potential difference can also be found in other ways. The potential difference in an '''uniform field''' is '''<math>∆{V} = -({E}_{x}∆{x} + {E}_{y}∆{y} + {E}_{z}∆{z})</math>''', which can also be written as '''<math>∆{V} = -\vec{E}·∆\vec{l}</math>'''.
DeltaV = -Efield (dot product) deltaL 
Remember that dot product of 2 vetors = (magnitude of vector1)*(magnitude of vector 2)*cos(angle between them)


How to determine the sign of potential difference:
'''∆V''' is the electric potential difference, which is measured in Joules per Coulomb (J/C), or just Volts (V). '''E''' is the electric field, which is measured in Newtons per Coulomb (N/C), and it is important to note that the different direction components of the electric field are used in the equation. '''l''' (or the '''x''', '''y''', '''z''') is the distance between the two described locations, which is measured in meters, and x, y, and z, are the different components of the difference.
If your path that you are considering goes in the same direction as the electric field, the sign will be negative (-)
If your path goes in the opposite direction of the electric field, the sign will be positive. (+)
If the path is perpendicular to the electric field, it will be zero.


Finding deltaV in nonuniform Fields:
The electric potential difference in a '''nonuniform field''' is '''<math>∆{V} = -∑ \vec{E}·∆\vec{l}</math>'''. The different parts in this particular equation resembles the equation for the potential difference in an uniform field, except that with the nonuniform field, the potential difference in the different fields are summed up. This situation can be quite easy, but when the system gets difficult, first, choose a path and divide it into smaller pieces of '''<math>∆\vec{l}</math>'''; second, write an expression for '''<math>∆{V} = -\vec{E}·∆\vec{l}</math>''' of one piece; third, add up the contributions of all the pieces; last, check the result to make sure the magnitude, direction, and units make sense.
DeltaV = -integral from (initial position to final position) of [Efield dot product deltaL]


Aside from just calculating the value of the electric potential difference, determining the sign is also quite crucial to be successful. If the path being considered is in the same direction as the electric field, then the sign with be negative (-). If the path being considered is in the opposite direction as the electric field, then the sign will be positive (+). If the path being considered is perpendicular to the electric field, then the potential difference will just be zero and have no direction. With these simple tips, the direction of the potential difference can be rechecked with the answer calculated using vectors.


'''Some Key Points'''
Also, when working with different situations, it is nice to keep in mind that in a conductor, the electric field is zero. Therefore, the potential difference is zero as well. In an insulator, the electric field is '''<math>{E}_{applied} / K</math>''' where '''K''' is the dielectric constant. Also, the round trip potential difference is always zero, or in other words, if you start from a certain point and end at the same point, then, the potential difference will be zero.  
- In a conductor we know that the electric field is zero. Therefore, the potential difference is zero as well(since it is constant everywhere).
- The potential difference between 2 locations does not depend on the path taken between the locations.
- Round Trip Potential Difference is always zero, If you start your path from a certain points and end your path at the same point, deltaV will be zero.
- In an insultor, the electric field is (Eapplied/K)m where K is a dielectric constant.Therefore, DeltaV = (deltaV inside vaccum)/K


===A Computational Model===
===A Computational Model===
Watch this video for a more visual approach  
Click on the link to see Electric Potential through VPython!
 
Make sure to press "Run" to see the principle in action!
 
[https://trinket.io/embed/glowscript/0a7e486c94 Teach hand-on with GlowScript]
 
Watch this video for a more visual approach!
 
[https://www.youtube.com/watch?v=-Rb9guSEeVE]
[https://www.youtube.com/watch?v=-Rb9guSEeVE]


==Examples==
==Examples==

Revision as of 15:53, 17 April 2016

AUTHOR: Rmohammed7 REVISED BY: HAYOUNG KIM (SPRING 2016)

This page discusses the Electric Potential and examples of how it is used.


The Main Idea

Electric potential is a rather difficult concept as it is usually accompanied by other topics. For example, electric potential is not the same as electric potential energy as electric potential is defined as the total potential energy per charge and is basically used to describe the electric field's effect at a certain location. In other words, electric potential is purely dependent on the electric field (whether it is uniform or nonuniform) and the location, whereas the electric potential energy also depends on the amount of charge the object in the system is experiencing. Also, although electric potential is an important topic to learn, most problems encountered will not ask to find just the "electric potential," instead, questions will most likely ask for the "electric potential difference." This is because electric potential is measured using different locations, or more specifically pathways between the different locations, so instead of determining the electric potential of location A and the electric potential of final location B, it would make more sense to determine the "difference in electric potential between locations A and B."

A Mathematical Model

Like mentioned in the Main Idea, instead of electric potential, in most cases, electric potential difference is needed to be found. The general equation for the potential difference is [math]\displaystyle{ ∆{{U}_{electric}} = {q} * ∆{V} }[/math].

[math]\displaystyle{ ∆{{U}_{electric}} }[/math] is the electric potential energy, which is measured in Joules (J). q is the charge of the particle moving through the path of the electric potential difference, which is measured in coulombs (C). ∆V is the electric potential difference, which is measured in Joules per Coulomb (J/C), or just Volts (V).

Aside from the general equation, the electric potential difference can also be found in other ways. The potential difference in an uniform field is [math]\displaystyle{ ∆{V} = -({E}_{x}∆{x} + {E}_{y}∆{y} + {E}_{z}∆{z}) }[/math], which can also be written as [math]\displaystyle{ ∆{V} = -\vec{E}·∆\vec{l} }[/math].

∆V is the electric potential difference, which is measured in Joules per Coulomb (J/C), or just Volts (V). E is the electric field, which is measured in Newtons per Coulomb (N/C), and it is important to note that the different direction components of the electric field are used in the equation. l (or the x, y, z) is the distance between the two described locations, which is measured in meters, and x, y, and z, are the different components of the difference.

The electric potential difference in a nonuniform field is [math]\displaystyle{ ∆{V} = -∑ \vec{E}·∆\vec{l} }[/math]. The different parts in this particular equation resembles the equation for the potential difference in an uniform field, except that with the nonuniform field, the potential difference in the different fields are summed up. This situation can be quite easy, but when the system gets difficult, first, choose a path and divide it into smaller pieces of [math]\displaystyle{ ∆\vec{l} }[/math]; second, write an expression for [math]\displaystyle{ ∆{V} = -\vec{E}·∆\vec{l} }[/math] of one piece; third, add up the contributions of all the pieces; last, check the result to make sure the magnitude, direction, and units make sense.

Aside from just calculating the value of the electric potential difference, determining the sign is also quite crucial to be successful. If the path being considered is in the same direction as the electric field, then the sign with be negative (-). If the path being considered is in the opposite direction as the electric field, then the sign will be positive (+). If the path being considered is perpendicular to the electric field, then the potential difference will just be zero and have no direction. With these simple tips, the direction of the potential difference can be rechecked with the answer calculated using vectors.

Also, when working with different situations, it is nice to keep in mind that in a conductor, the electric field is zero. Therefore, the potential difference is zero as well. In an insulator, the electric field is [math]\displaystyle{ {E}_{applied} / K }[/math] where K is the dielectric constant. Also, the round trip potential difference is always zero, or in other words, if you start from a certain point and end at the same point, then, the potential difference will be zero.

A Computational Model

Click on the link to see Electric Potential through VPython!

Make sure to press "Run" to see the principle in action!

Teach hand-on with GlowScript

Watch this video for a more visual approach!

[1]


Examples

Be sure to show all steps in your solution and include diagrams whenever possible

Simple

Middling

A proton is located at the origin. Location C is 1e-10 m away from the proton, and location D is 2e-8 m from the proton, along a straight line radially outward. First, find the potential difference from C to D. Then find how much work would be required to move an electron from location C to D.

Connectedness

  1. How is this topic connected to something that you are interested in?

I am interested in robotic systems and building circuit boards/ electrical systems for manufacturing robots. While studying this section in the book, I was able to connect back many of the concepts and calculations back to robotics and electrical component of autmated systems.

  1. How is it connected to your major?

I am a Mechanical Engineering major, so I will be dealing with electrical components of machines when I work. Therefore, I have to know these certain concepts such as electric potential in order to fully understand how they work and interact.

  1. Is there an interesting industrial application?

Electrical Potential is used to find the voltage across a path. This is useful when working with circuit comppnents and attempting to manupulate the power output or current throught a component.

History

The idea of electric potential kind of started with Ben Franklin and his experiments in the 1740s. He began to understand the flow of electricity, which eventually paved the path towards explaining electric potential and potential difference. Scientist finally began understading how electric fields were actually affecting the surrounding environment and other charges. Benjamin Franklin first shocked himself in 1746, while conducting experiments on electricity with found objects from around his house. Six years later 261 years ago, the founding father flew a kite attached to a key and a silk ribbon in a thunderstorm and effectively trapped lightning in a jar. The experiment is now seen as a watershed moment in mankind's venture to channel a force of nature so abstract.

By the time Franklin started experimenting with electricity, he'd already found fame and fortune as the author of Poor Richard's Almanack and was starting to get into science. Electricity wasn't a very well understood phenomenon at that point, though, so Franklin's research proved to be fairly foundational. The early experiments, experts believe, were inspired by other scientists' work and the shortcomings therein.

That early brush with the dangers of electricity left an impression on Franklin. He described the sensation as "a universal blow throughout my whole body from head to foot, which seemed within as well as without; after which the first thing I took notice of was a violent quick shaking of my body." However, it didn't scare him away. In the handful of years before his famous kite experiment, Franklin contributed everything from designing the first battery designs to establishing some common nomenclature in the study of electricity.

See also

Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?

Further reading

Here are some cool articles about the topic [2]

References

This section contains the the references you used while writing this page

Youtube.com

Matter and Interactions: Electric and Magnetic Interactions Volume 2

Modern Physics Wiki