The Photovoltaic Effect: Difference between revisions

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The photovoltaic effect is the creation of electric current or voltage through a material upon exposure to light. It is a physical and chemical phenomenon in response to the transfer of energy from photons.
The photovoltaic effect is the creation of electric current or voltage through a material upon exposure to light. It is a physical and chemical phenomenon in response to the transfer of energy from photons.
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== The Main Idea ==
== The Main Idea ==


The photovoltaic effect is directly related to [https://en.wikipedia.org/wiki/Photoelectric_effect The Photoelectric Effect], but they are different processes. When light strikes a material surface, the electrons present in the valence band absorb the energy from the photons energy and, being excited, jump to the conduction band and become free. The material is composed of crystallized atoms that are ionized and create an electric imbalance, that drives the electrons. These highly excited electrons diffuse and some reach a junction where they are accelerated into a different material by an electrode. This generates an electric current, so some of the light energy can be converted into electric energy. This current can then be used to power an appliance.
The photovoltaic effect is directly related to [https://en.wikipedia.org/wiki/Photoelectric_effect The Photoelectric Effect], but they are different processes. When light strikes a material surface, the electrons present in the [https://en.wikipedia.org/wiki/Valence_and_conduction_bands valence band] absorb the energy from the [https://en.wikipedia.org/wiki/Photon photons] and, being excited, jump to the conduction band and become free. The material is composed of crystallized atoms that are ionized and create an electric imbalance, that helps to drive the electrons. These highly excited electrons diffuse and some reach a junction where they are accelerated into a different material by an [https://en.wikipedia.org/wiki/Electrode electrode]. This generates an electric current, so some of the light energy can be converted into electric energy. This current can then be used to power an appliance.


== Application ==


== Application ==
[[File:wiki.png|260px|thumb|left|'''A Photovoltaic Cell''']]


[[File:wiki.png|200px|thumb|left|'''A Photovoltaic Cell''']]
The photovoltaic effect is the evacuation of from a material due to the energy from photons in an [http://www.sekonic.com/l-478/incident-vs-reflected.html incident light]. We can harness the energy from this reaction with photovoltaic cells. This is because of the design on the photovoltaic or solar cell. The most basic of these cells are designed merely with two layers of a metalloid and an electrode. The top, or [https://en.wikipedia.org/wiki/P%E2%80%93n_junction p-type] layer of metalloid is generally composed of Boron [https://en.wikipedia.org/wiki/Doping_(semiconductor) doped] silicon. This is because the added Boron creates a dearth of electrons on the top layer. The bottom, or [https://en.wikipedia.org/wiki/P%E2%80%93n_junction n-type] layer of the cell is usually made of a Phosphorous doped silicon. This creates a highly negative layer, which in conjunction with the positive p-type layer, creates a charge gradient that allows for the movement of free electrons and is the basis for photovoltaic cells.


The photovoltaic effect is the evacuation of from a material due to the energy from photons in an incident light. We can harness the energy from this reaction with photovoltaic cells. This is because of the design on the photovoltaic or solar cell. The most basic of these cells are designed merely with two layers of a metalloid and an electrode. The top, or [https://en.wikipedia.org/wiki/P%E2%80%93n_junction p-type] layer of metalloid is generally composed of Boron [https://en.wikipedia.org/wiki/Doping_(semiconductor) doped] silicon. This is because the added Boron creates a dearth of electrons on the top layer. The bottom, or [https://en.wikipedia.org/wiki/P%E2%80%93n_junction n-type] layer of the cell is usually made of a Phosphorous doped silicon. This creates a highly negative layer, which in conjunction with the positive p-type layer, creates a charge gradient that allows for the movement of free electrons and is the basis for photovoltaic cells.


Where the p-type and n-type layers meet, they form an electromagnetically stable barrier between the two layers that only allows electrons to flow from the p-type layer to the n-type layer. This allows electrons to flow into the n-type layer through the p-n junction boundary. The free electrons then return to the p-type layer by flowing through the [https://en.wikipedia.org/wiki/Electrode electrode.] This flow of electrons is what we call electricity, and it allows for the cyclical nature of the photovoltaic cell while also powering our technology.   
Where the p-type and n-type layers meet, they form an electromagnetically stable barrier between the two layers that only allows electrons to flow from the p-type layer to the n-type layer. This allows electrons to flow into the n-type layer through the [https://en.wikipedia.org/wiki/P%E2%80%93n_junction p-n junction boundary]. The free electrons then return to the p-type layer by flowing through the electrode. This flow of electrons is what we call electricity, and it allows for the                                     cyclical nature of the photovoltaic cell while also powering our technology.   


=== Electrode Configuration ===
=== Electrode Configuration ===


==== Forward Bias ====
==== Forward Bias ====
With a forward bias, the p-type layer is connected to the positive terminal of the electrode, and the n-type layer is connected to the negative side.  Reducing depletion width occurs because of the shrinking charge profile, as fewer dopants are exposed with increasing forward bias. When the photovoltaic cell is connected in this manner, the holes from the p-type region and the electrons in the n-type region are forced toward the junction. This reduces the width of the buffer zone. The positive charge of the p-type material repels the holes, while the negative energy of the n-type material repels the electrons.
With a [http://www.science-campus.com/engineering/electronics/semiconductor_theory/diode_3.html forward bias], the p-type layer is connected to the positive terminal of the electrode, and the n-type layer is connected to the negative side.  Reducing depletion width occurs because of the shrinking charge profile, as fewer dopants are exposed with increasing forward bias. When the photovoltaic cell is connected in this manner, the [https://en.wikipedia.org/wiki/Electron_hole holes] from the p-type region and the electrons in the n-type region are forced toward the junction. This reduces the width of the buffer zone. The positive charge of the p-type material repels the holes, while the negative energy of the n-type material repels the electrons.


==== Reverse Bias ====
==== Reverse Bias ====
In order to switch to a reverse bias, you simply swap the position of the electrode terminals. If a cell is reverse-biased, the voltage at the cathode is comparatively higher than the anode. Therefore, no current will flow until the depletion zone breaks down. Because the p-type layer is connected to the negative terminal, the "holes" in the p-type material are pulled away from the junction, and because the n-type layer is connected to the positive terminal, the electrons are pulled away from the junction. This results in the growth of the depletion zone. This increases the voltage barrier causes a high resistance to the flow of electricity, thus allowing very little current to cross what is now a functional insulator, the p–n junction.
In order to switch to a [http://www.science-campus.com/engineering/electronics/semiconductor_theory/diode_2.html reverse bias], you simply swap the position of the electrode terminals. If a cell is reverse-biased, the voltage at the cathode is comparatively higher than the anode. Therefore, no current will flow until the depletion zone breaks down. Because the p-type layer is connected to the negative terminal, the "holes" in the p-type material are pulled away from the junction, and because the n-type layer is connected to the positive terminal, the electrons are pulled away from the junction. This results in the growth of the depletion zone. This increases the voltage barrier causes a high resistance to the flow of electricity, thus allowing very little current to cross what is now a functional insulator, the p–n junction.


== Light Generated Current ==
== Light Generated Current ==
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== History ==  
== History ==  
The photovoltaic effect was discovered by a French physicist, Edmund Bequerel, in 1839, who found that certain materials would produce small amounts of electric current when irradiatedt. The first photovoltaic module was built by Bell Laboratories in 1954. It was billed as a solar battery and was mostly just a curiosity piece as it was too expensive to gain widespread use.
The photovoltaic effect was discovered by a French physicist, [https://en.wikipedia.org/wiki/Edmond_Becquerel Edmund Bequerel], in 1839, who found that certain materials would produce small amounts of electric current when irradiatedt. The first photovoltaic [http://ethw.org/Milestones:First_Practical_Photovoltaic_Solar_Cell module] was built by Bell Laboratories in 1954. It was billed as a solar battery and was mostly just a curiosity piece as it was too expensive to gain widespread use.
 


This trend still continues today as solar power technology is expensive and inefficient.
This trend still continues today as solar power technology is expensive and inefficient.
Line 39: Line 40:
== Connectedness ==  
== Connectedness ==  


This topic is particularly interesting to me because I am a Materials Science and Engineering student. This scientific phenomena is heavily involved with the structure of the different materials involved. I am actually looking at researching next generation photovoltaic materials in the spring, so this project was a good study/introduction into the topic.
 
 
This topic should be very important to all of us because we as a species are very quickly exhausting all of our non-renewable energy resources, and photovoltaic technology may be the solution. This topic is particularly interesting to me because I am a Materials Science and Engineering student. This scientific phenomena is heavily involved with the structure of the different materials involved. I am actually looking at researching next generation photovoltaic materials in the spring, so this project was a good study/introduction into the topic.


== See Also ==
== See Also ==
 
{| cellpadding=5
{{colbegin}}
|
{{Anomalous photovoltaic effect}}
* [https://en.wikipedia.org/wiki/Anomalous_photovoltaic_effect Anomalous photovoltaic effect]
Autonomous building
* [https://en.wikipedia.org/wiki/Black_silicon Black silicon]
Black silicon
* [https://en.wikipedia.org/wiki/Electromotive_force#Solar_cell Electromotive force (Solar cell)]
Energy development
* [https://en.wikipedia.org/wiki/Green_technology Green technology]
Electromotive force (Solar cell)
* [https://en.wikipedia.org/wiki/Inkjet_solar_cell Inkjet solar cell]
Flexible substrate
* [https://en.wikipedia.org/wiki/List_of_types_of_solar_cells List of types of solar cells]
Green technology
||
Inkjet solar cell
* [https://en.wikipedia.org/wiki/Metallurgical_grade_silicon Metallurgical grade silicon]
List of photovoltaics companies
* [https://en.wikipedia.org/wiki/Photovoltaics Photovoltaics]
List of types of solar cells
* [https://en.wikipedia.org/wiki/P%E2%80%93n_junction P–n junction]
Maximum power point tracking
* [https://en.wikipedia.org/wiki/Plasmonic_solar_cell Plasmonic solar cell]
Metallurgical grade silicon
* [https://en.wikipedia.org/wiki/Printed_electronics Printed electronics]
Microgeneration
* [https://en.wikipedia.org/wiki/Quantum_efficiency Quantum efficiency]
Nanoflake
||
Photovoltaics
* [https://en.wikipedia.org/wiki/Renewable_energy Renewable energy]
{{col-break}}
* [https://en.wikipedia.org/wiki/Solar_Energy_Materials_and_Solar_Cells ''Solar Energy Materials and Solar Cells (journal)'']
{{P–n junction}}
* [https://en.wikipedia.org/wiki/Solar_shingles Solar shingles]
Plasmonic solar cell
* [https://en.wikipedia.org/wiki/Spectrophotometry Spectrophotometry]
Printed electronics
* [https://en.wikipedia.org/wiki/Theory_of_solar_cells Theory of solar cells]
Quantum efficiency
* [https://en.wikipedia.org/wiki/Thermophotovoltaics Thermophotovoltaics]
Renewable energy
|}
Roll-to-roll processing
Shockley-Queisser limit
Solar Energy Materials and Solar Cells (journal)
Solar module quality assurance
Solar roof
Solar shingles
Solar tracker
Spectrophotometry
Theory of solar cells
Thermophotovoltaics
{{colend}}


== References ==
== References ==

Latest revision as of 13:58, 6 December 2015

Created by Andrew Kresses

The photovoltaic effect is the creation of electric current or voltage through a material upon exposure to light. It is a physical and chemical phenomenon in response to the transfer of energy from photons.

A collection of Photovoltaic cells, also known as a Solar Panel


The Main Idea

The photovoltaic effect is directly related to The Photoelectric Effect, but they are different processes. When light strikes a material surface, the electrons present in the valence band absorb the energy from the photons and, being excited, jump to the conduction band and become free. The material is composed of crystallized atoms that are ionized and create an electric imbalance, that helps to drive the electrons. These highly excited electrons diffuse and some reach a junction where they are accelerated into a different material by an electrode. This generates an electric current, so some of the light energy can be converted into electric energy. This current can then be used to power an appliance.

Application

A Photovoltaic Cell

The photovoltaic effect is the evacuation of from a material due to the energy from photons in an incident light. We can harness the energy from this reaction with photovoltaic cells. This is because of the design on the photovoltaic or solar cell. The most basic of these cells are designed merely with two layers of a metalloid and an electrode. The top, or p-type layer of metalloid is generally composed of Boron doped silicon. This is because the added Boron creates a dearth of electrons on the top layer. The bottom, or n-type layer of the cell is usually made of a Phosphorous doped silicon. This creates a highly negative layer, which in conjunction with the positive p-type layer, creates a charge gradient that allows for the movement of free electrons and is the basis for photovoltaic cells.


Where the p-type and n-type layers meet, they form an electromagnetically stable barrier between the two layers that only allows electrons to flow from the p-type layer to the n-type layer. This allows electrons to flow into the n-type layer through the p-n junction boundary. The free electrons then return to the p-type layer by flowing through the electrode. This flow of electrons is what we call electricity, and it allows for the cyclical nature of the photovoltaic cell while also powering our technology.

Electrode Configuration

Forward Bias

With a forward bias, the p-type layer is connected to the positive terminal of the electrode, and the n-type layer is connected to the negative side. Reducing depletion width occurs because of the shrinking charge profile, as fewer dopants are exposed with increasing forward bias. When the photovoltaic cell is connected in this manner, the holes from the p-type region and the electrons in the n-type region are forced toward the junction. This reduces the width of the buffer zone. The positive charge of the p-type material repels the holes, while the negative energy of the n-type material repels the electrons.

Reverse Bias

In order to switch to a reverse bias, you simply swap the position of the electrode terminals. If a cell is reverse-biased, the voltage at the cathode is comparatively higher than the anode. Therefore, no current will flow until the depletion zone breaks down. Because the p-type layer is connected to the negative terminal, the "holes" in the p-type material are pulled away from the junction, and because the n-type layer is connected to the positive terminal, the electrons are pulled away from the junction. This results in the growth of the depletion zone. This increases the voltage barrier causes a high resistance to the flow of electricity, thus allowing very little current to cross what is now a functional insulator, the p–n junction.

Light Generated Current

This expression defines the light-generated current in a photovoltaic cell, IL, as a function of solar radiation and the temperature of the cell. ST represents the intitial solar radiation, and ST,r denotes the reflected solar radiation. Tc and Tc,r are the cell temperatures before and after irradiation. IL,r is light-generated current at reference conditions, and μIsc is coefficient of temperature at short circuit current. The initial cell temperature, Tc, can be computed from the ambient reference temperature.

History

The photovoltaic effect was discovered by a French physicist, Edmund Bequerel, in 1839, who found that certain materials would produce small amounts of electric current when irradiatedt. The first photovoltaic module was built by Bell Laboratories in 1954. It was billed as a solar battery and was mostly just a curiosity piece as it was too expensive to gain widespread use.


This trend still continues today as solar power technology is expensive and inefficient.

Connectedness

This topic should be very important to all of us because we as a species are very quickly exhausting all of our non-renewable energy resources, and photovoltaic technology may be the solution. This topic is particularly interesting to me because I am a Materials Science and Engineering student. This scientific phenomena is heavily involved with the structure of the different materials involved. I am actually looking at researching next generation photovoltaic materials in the spring, so this project was a good study/introduction into the topic.

See Also

References

"P-N Junction." Hyper Physics. Georgia State, n.d. Web. 06 Dec. 2015.

Knier, Gil. "How Do Photovoltaics Work?" National Aeronautics and Space Administration. NASA Science, 2002. Web. 06 Dec. 2015.

Jakhrani, Abdul Quayoom. "An Improved Mathematical Model for Computing Power Output of Solar Photovoltaic Modules." International Journal of Photoenergy. Hindawi Publishing Corporation, 17 Mar. 2014. Web. 4 Dec. 2015.

Wikipedia contributors. "Photovoltaics." Wikipedia, The Free Encyclopedia. Wikipedia, The Free Encyclopedia, 3 Dec. 2015. Web. 6 Dec. 2015.