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The Sun

The Sun. The Sun. Big Bang nucleosynthesis 5 billion years old, 5 billion more years before death Radiated energy determines age Diameter 110 x earth, 99.86% mass of solar system ~90 million miles from earth = 1 AU, ~8 minutes for light ~75% H, 23% He, rest heavy elements, 2% heavy elements

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The Sun

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  1. The Sun

  2. The Sun • Big Bang nucleosynthesis • 5 billion years old, 5 billion more years before death • Radiated energy determines age • Diameter 110 x earth, 99.86% mass of solar system • ~90 million miles from earth = 1 AU, ~8 minutes for light • ~75% H, 23% He, rest heavy elements, 2% heavy elements • Surface temperature ~6,000°C • 1.4x103 kg/m3, 24 x g ,(water 1.0x103 kg/m3) • Nuclear Fusion – 500,000 tons H/sec • 100 earths so far • Brighter than 85% of stars in Milky Way – Red Dwarfs

  3. Blackbody Radiation Thermal Radiation Is Electromagnetic Radiation Emitted From A Material Which Is Due To Its Temperature

  4. The Sun • Magnetically active, 11 year cycle: • Sunspots, Solar flares • Solar wind (disruption of communications and electric power) • Made of gas and plasma • H fusion now, He in 5 billion years • Stellar nucleosynthesis

  5. Sunspots and the Sunspot Cycle

  6. Photovoltaics

  7. How Much Solar Irradiance Do You Get?

  8. Solar Cell Land Area Requirements for the World’s Energy with Solar PV 6 Boxes at 3.3 TW Each

  9. A Brief History Photovoltaic Technology • 1839 – Photovoltaic effect discovered by Becquerel • 1870s – Hertz developed solid selenium PV (2%) • 1905 – Photoelectric effect explained by A. Einstein • 1930s – Light meters for photography commonly employed cells of copper oxide or selenium • 1954 – Bell Laboratories developed the first crystalline silicon cell (4%) • 1958 – PV cells on the space satellite U.S. Vanguard (better than expected)

  10. Things Start To Get Interesting... • mid 1970s – World energy crisis = millions spent in research and development of cheaper more efficient solar cells • 1976 – First amorphous silicon cell developed by Wronski and Carlson • 1980’s - Steady progress towards higher efficiency and many new types introduced • 1990’s - Large scale production of solar cells more than 10% efficient with the following materials: • Ga-As and other III-V’s • CuInSe2 andCdTe • TiO2 Dye-sensitized • Crystalline, Polycrystalline, and Amorphous Silicon • Today, prices continue to drop and new “3rd generation” solar cells are researched

  11. Types of Solar Photovoltaic Materials

  12. Photovoltaic Materials

  13. Energy Bands in a Semiconductor • Conduction Band – Ec – empty • Valence Band – Ev – full of electrons

  14. 3 Types of Semiconductors • Intrinsic • n-type • p-type • Types 2 and 3 are semiconductors that conduct electricity - How? • By alloying semiconductor with an impurity, also known as doping • Carriers placed in conduction band or carriers removed from valence band

  15. p-n and p-i-n Junctions Vbi Vbi Ef Ef

  16. Schottky Barriers and Heterojunctions • A Schottky barrier is a potential barrier formed at a metal–semiconductor junction which has rectifying characteristics, suitable for use as a diode • The largest differences between a Schottky barrier and a p–n junction are its typically lower junction voltage, and decreased (almost nonexistent) depletion width in the metal

  17. I-V Curve for Solar Cells

  18. Light Absorption by a Semiconductor • Photovoltaic energy relies on light • Light → stream of photons → carries energy • Example: On a clear day 4.4x1017 photons hit 1 m2 of Earth’s surface every second. • Eph()=hc/ • h = plank’s constant = 6.625 x 10-34 J-s •  = wavelength • c = speed of light =3 x 108 m/s • f = frequency • However, only photons with energy in excess of bandgap can be converted into electricity by solar cells

  19. The Solar Spectrum The entire spectrum is not available to single junction solar cell

  20. Generation of Electron Hole Pairs with Light • Photon enters, is absorbed, and lets electron from VB get sent up to CB • Therefore a hole is left behind in VB, creating absorption process: electron-hole pairs • Because of this, only part of solar spectrum can be converted • The photon flux converted by a solar cell is about 2/3 of total flux

  21. Electron Flow in a PV Cell

  22. Generation Current • Generation Current = light induced electrons across bandgap as electron current • Electron current:= Ip=qNA • N = # of photons in highlighted area of spectrum • A = surface area of semiconductor that’s exposed to light • Because there is current from light, voltage can also occur • Electric power can occur by separating the electrons and holes to the terminals of device • Electrostatic energy of charges occurs after separation only if its energy is less than the energy of the electron-hole pair in semiconductor • Therefore, Vmax=Eg/q • Vmax= bandgap of semiconductor is in EV’s, therefore this equation shows that wide bandgap semiconductors produce higher voltage

  23. Different Types of Photovoltaic Solar Cells Diffusion Drift Excitonic

  24. Diffusion • n-type and p-type are aligned by the Fermi-level • When a photon comes in n-type, it takes the place of a hole, the hole acts like an air bubble and “floats” up to the p-type • When the photon comes to the p-type, it takes place of an electron, the electron acts like a steel ball and “rolls” down to the n-type

  25. Power Losses in Solar Cells

  26. Recombination • Opposite of carrier generation, where electron-hole pair is annihilated • Most common at: • impurities • defects of crystal structure • surface of semiconductor • Reducing both voltage and current

  27. Tandem Cells Silver Grid • Tandem cell- several cells, • Top cell has large bandgap • Middle cell mid eV bandgap • Bottom cell small bandgap Indium Tin Oxide p-a-Si:H Blue Cell i-a-Si:H n-a-Si:H p Green Cell i-a-SiGe:H (~15%) n p Red Cell i-a-SiGe:H (~50%) n Textured Zinc Oxide Silver Stainless Steel Substrate Schematic diagram of state-of-the-art a-Si:H based substrate n-i-p triple junction cell structure

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