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Basic Science and Modeling
ofSolar Energy
byJeremy Parra and Sandrio Elim
SCI 322U – Energy and Society II PresentationSCI 322U – Energy and Society II PresentationBy Jeremy Parra and Sandrio ElimBy Jeremy Parra and Sandrio Elim 11
Topics:
• Science of Solar EnergyScience of Solar Energy
• Technology Using Solar EnergyTechnology Using Solar Energy
SCI 322U – Energy and Society II PresentationSCI 322U – Energy and Society II PresentationBy Jeremy Parra and Sandrio ElimBy Jeremy Parra and Sandrio Elim 22
Science of Solar Energy
•Resources: •Energy Flows:•Chemistry and Physics background:
SCI 322U – Energy and Society II PresentationSCI 322U – Energy and Society II PresentationBy Jeremy Parra and Sandrio ElimBy Jeremy Parra and Sandrio Elim 33
“The pp-chain (proton-proton chain) involves a series of nuclear reactions that are responsible for the generation of energy in the sun. The basis for the suns energy is that four hydrogen atoms fuse to form one helium atom whose mass is slightly less than the mass of the combined four hydrogen atoms. The missing mass is what was converted to energy.
“In the pp-chain, two protons (moving at very fast velocities) fuse together to create deuterium. A neutrino and a positron are expelled in the process. Deuterium (one proton and one neutron) fuse with one more proton creating Helium-3. A photon is released in this process and this is what gives the sun it's energy. After Helium-3 is created, it fuses with another of its type and 2 hydrogen atoms are expelled. The result is one atom of Helium-4 and 2 atoms of Hydrogen to start the process all over again. Even though the photons are accountable for most of the sun's energy, about 5% of the energy is given off in neutrinos.”
-bib. 1
Fig. 1 (copied ,bib.1)
Solar fusion
Hydrogen(one proton)
HHelectron
Hydrogen
H2
Deuterium(one proton one neutron)
electron
positron neutrino
H
Deuterium
He
Helium(two protons one neutron)
3
γ photon
He3
Helium
H
H
He3
Yield
Sun Light
Photon
If when a photon strikes an electron it has the amount of energy to break the electron-electron bond( band gap) a free electron will result.
This results in a positive “hole” and a negative electron.
Hole
Free electronPhoton
Semiconductors
A semiconductor has electrical conductivity greater that insulators but less than good conductors.
Silicon has four valence electrons.
Pure silicon is in a perfect state of valence(has no free electrons).
Si
electrons
hole
Free electron
Silicon
nucleus
Semiconductors
When phosphorous is substituted for a silicon atom, there is one electron left
The remaining electron is very loosely bound by the slightly more positive charge of the nucleus of the phosphorous atom.
This electron travels easily around the phosphorous atom.
Silicon that contains a large number of atoms with an extra valence electron is called n type silicon (n is for negative).
Si P
SiSi
SiSi
Si Si
Extra Electron
N-Type
Semiconductors
If a boron atom is substituted for a silicon atom, there is one valence electron which has no partner.
This missing electron is a hole. This yields a positive charge (the absence of an
negative electron). This is a p-type
Si B
SiSi
Hole
P-Type
Si
Si
The binding force of electron pairs is much stronger than the electromagnetic force between an electron and the nucleus
The extra electron moves from the n-type to the p-type And these electrons form valence pairs with the electrons
that were missing a pair This results in a shift in charge that creates an electric field
in the material. Now the n-side(doped with phosphorus) gains a positive
charge. When the electron moved it left a proton “Similarly, the boron atom is surrounded by one more
electron than there are positive protons in the boron nucleus.”
Electric Field
The n-type side doped with Phosphorus easily lends its free electron to the positive side (doped with boron).
This leaves the n-type with one more proton than electron giving the n-type a positive charge.
And the p-type now has one more electron the proton yielding a negative charge.
This creates an electric field. With out this electric field the freed electron(freed by a photon) would just return to the same hole.
But because of the electric field the freed electron will move from the negative area to the positive area creating an electric current. And the holes will move in the other direction.
Technology Using Solar Energy• Types of cells:
1. Crystalline Silicona. Single crystalb. Multi-crystallinec. Ribbond. Film
2. Thin films materialsa. Amorphous Siliconb. Cadmium Telluridec. Copper Indium Diselenide
3. Concentrators• Components:
1. PV2. DC-AC Converter3. Backup Power Generator4. Stabilizer5. Electrical Panel
SCI 322U – Energy and Society II PresentationSCI 322U – Energy and Society II PresentationBy Jeremy Parra and Sandrio ElimBy Jeremy Parra and Sandrio Elim 2323
Source:DOE/GO-10097-377 FS 231 - March 1997
Types of PV Cells
1. Monocrystalline Silicon Cells2. Multicrystalline Silicone Cells3. Thick-film Silicon4. Amorphous Silicon5. Other thin films:
• Cadmium telluride• Copper indium diselenide• Gallium arsenide• Tandem cells
1. Monocrystalline Silicon
•Most efficient PV tech•Complicated process•High Cost to manufacture
2. Multicrystalline Silicon
•Cheaper•Simpler process•Less efficiency•Granular texture
3. Thick-film Silicon
•Continuous process•Fine grained•Bounded to aluminum frame
4. Amorphous Silicon
•A thin homogenous layer•More effective in absorbing lights•Also known as thin film PV•Efficiency about 6%
5. Other Thin Filmsa. Cadmium telluride and Copper indium diselenide
• Still in research• Very inexpensive process• Expected efficiency quite high
b. Gallium arsenide• High efficiency• Relatively temperature independent• For special purpose only
c. Tandem cells• Made of two different cells• Usually from silicon and gallium arsenide• Better use of incoming light
Manufacturing
How It Works
Math Modeling
SCI 322U – Energy and Society II PresentationSCI 322U – Energy and Society II PresentationBy Jeremy Parra and Sandrio ElimBy Jeremy Parra and Sandrio Elim 3232
1. Optimal Conditionsa. Equationsb. Independent Variables
2. Method of Data Collectiona. Softwareb. Units
Source:DOE/GO-10097-377 FS 231 - March 1997
Source:DOE/GO-10097-377 FS 231 - March 1997
Bibliography
1) http://cosmos.colorado.edu/~hairgrov/Sun's_Energy_Generation
2) http://www.wikipedia.org/wiki/Deuterium
3) http://pearl1.lanl.gov/periodic/elements/1.html
4) http://www.nobel.se/chemistry/laureates/2000/public.html
5) http://www.scolar.org.uk/html/pdf-page.html
6) http://sol.crest.org/renewables/re-kiosk/solar/pv/theory/index.shtml
7) http://www.fsec.ucf.edu/pvt/pvbasics/
8) http://www.ips-solar.com/basics/solarbasics.htm
9) http://acre.murdoch.edu.au/refiles/pv/text.html
