Arie Zaban Department of Chemistry Institute for Nanotechnology and Advanced Materials

1. מגמות במחקר סולארי בעולם ובישראל: לאיפה אפשר להגיע ומה דרוש Arie Zaban Department of Chemistry Institute for Nanotechnology and Advanced Materials Bar-Ilan University, Israel

2. The Need/Challenge: 10TW Renewable Energy North America’s Largest Solar-Electric Plant Switched On (28/12/2007) 14 MW power plant at the Nellis Air Force Base (south Nevada). ~30 million kilowatt-hours (30MWh) of electricity annually. Expected to reduce carbon dioxide emissions by 24,000 tons/year. Contraction cost: $100 million. Land: 140 acres (570 dunam). The company that owns the panels is leasing the land at no cost, and Nellis is agreeing to buy the power for 20 years at about 2.2 cents/kWh, instead of the 9 cents they are paying to Nevada Power, saving the Air Force $1 million each year. None of the $100 million cost came from the Air Force.

3. The Need/Challenge: 10TW Renewable Energy North America’s Largest Solar-Electric Plant Switched On (28/12/2007) 14 MW power plant at the Nellis Air Force Base (south Nevada). One plant, every hour, for the next: 81 years

4. The Need/Challenge: 10TW Renewable Energy • 2012 installation = 24GW • one plant every 5 hrs. • >150G$ One plant, every hour, for the next: 81 years

5. Research Goals Energy Cost ($/KWh) • system cost ($/m2) • system efficiency (%) • effective sun (KWh/m2)

6. Best Research Cell Efficiencies

7. Single-Bandgap PV and the Solar Spectrum (AM 1.5)

8. Optimal Bandgap for Single Junction PV Prince, JAP 26 (1955) 534 Loferski, JAP 27 (1956) 777

9. Best Research Cell Efficiencies

10. Production, Laboratory, Theoretical PV Module Efficiency

11. Global PV Module Price Learning Curve for c-siWafer-Based and CdTe Modules, 1979 To 2015

12. Multi-Bandgap PV and the Solar Spectrum (AM 1.5)

13. Multi-Bandgap Photovoltaics • cost • concentration • current matching

14. Maximum Efficiency for Ideal Multi-Bandgap PV With optical losses Bennett and Olsen, 1988, IEEE PVSC, p. 868

15. Best Research Cell Efficiencies

16. Production, Laboratory, Theoretical PV Module Efficiency

17. Third Generation Options

18. Third Generation Options Up-Conversion for a Single Junction Down-Conversion for a Single Junction

19. Third Generation Options Multiple exciton generation (MEG) Phonon cooling Phonon cooling Auger recombination MEG

20. Third Generation Options Luminescent solar concentrators Plasmonic solar cells Antenna-based solar cells

21. Best Research Cell Efficiencies

22. Best Research Cell Efficiencies: Emerging PV

23. Research Goals Energy Cost ($/KWh) • system cost ($/m2) • system efficiency (%) • effective sun (KWh/m2)

24. System Cost Light collection (wave guide effect) Anti reflection coating Charge collection

25. Combinatorial Material (Absorber) Library All-Oxide PV: combinatorial material science Co3O4 conductance

26. Bright Future Needs: • Basic science • Material science • Long term funding (fuel replacement program) • Centers of excellence (nano) • Partnership with industry Co3O4

27. וְהָיוּ לִמְאוֹרֹת בִּרְקִיעַ הַשָּׁמַיִם, לְהָאִיר עַל הָאָרֶץ. Thank You and let them be lights in the expanse of the sky to give light on (upon) the earth.

28. The Photovoltaic (PV) Mechanism cosT breakdown of currenTconvenTionalpvsysTems in The uniTedsTaTes , 2010

29. The Photovoltaic (PV) Mechanism average worldwide pv module price level and Their cosTsTrucTure by Technology (2010).

30. Production, Laboratory, Theoretical PV Module Efficiency

31. QDSSCs: Co-Sensitization (in series)

32. Low Cost Multi-BandgapSolar CellsTwo Bands Spectral Splittingwith David Cahen and Igor Lubomirsky, WIS

33. Waveguide Based PV System high band-gap PV medium band-gap PV low band-gap PV hu refractive index matching

34. CdSe-QR Sensitized Solar Cell: Dipole Effect Nano Lett. (2012), 12, 2095