Roughly 4.6 billion years ago... Let there be light

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Bathsheba Lawson
5 years ago
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2 The Past

3 Roughly 4.6 billion years ago... Let there be light

4 1839 Edmund Becquerel discovers the photovoltaic effect Auguste Mouchout was the first man to patent a design for a motor running on solar energy.

5 1872 John Ericsson's developed his Sun Motor.

6 1873 Willoughby Smith experimented with the photocoductivity properties of selenium Charles Fritts made a solid state solar cell by coating selenium with a thin layer of gold.

1931 We are like tenant farmers chopping down the fence around our house for fuel when we should be using Nature's inexhaustible sources of energy sun, wind and tide.

7 1931 We are like tenant farmers chopping down the fence around our house for fuel when we should be using Nature's inexhaustible sources of energy sun, wind and tide.... I'd put my money on the sun and solar energy. What a source of power! I hope we don't have to wait until oil and coal run out before we tackle that. Thomas Edison, in conversation with Henry Ford and Harvey Firestone as quoted in Uncommon Friends : Life with Thomas Edison, Henry Ford, Harvey Firestone, Alexis Carrel & Charles Lindbergh (1987) by James Newton, p. 31

8 What a source of power indeed The amount of sunlight that hits the Earth's surface in one hour is enough to power the entire world for a year!

9 The solar constant, a measure of the amount of incoming solar radiation per unit area that would be incident on a plane perpendicular to the rays, at a distance of one astronomical unit (roughly the mean distance from the Sun to the Earth) kw/m²

atmosphere the sun provides ~ 89 x 10 15 W or 89

10 Integrated over the surface of the Earth and accounting for reflection and absorption in the atmosphere the sun provides ~ 89 x W or 89 PW Worldwide energy use per hour ~20 x W or 20 TW

11 6 Boxes at 3.3 TW Each

12 1940 Russell Ohl discovers the p-n junction 1941 Russell Ohl receives a US Patent , "Light sensitive device"

13 1954 AT&T Bell Labs unveils it new solar battery developed by Gerald Pearson, Daryl Chapin, and Calvin Fuller which was the first modern silicon solar cell.

14 Depletion Region Photo-excited carriers that are not collected either radiatively recombine or non-radiatively recombine (i.e., heat up the cell)

15 1950 s

1839 - photovoltaic effect discovered 1883 - first solar cell

- doped silicon first used in solar cells 1958 - first

operation 1989 - first dual junction cell created 1991 - NREL

1994-30% efficiency barrier broken 1996 - National Center for

100 MW 2004 - terrestrial PV shipments exceeds 1 GW 2006-40%

17 photovoltaic effect discovered first solar cell created modern pn junction solar cell demonstrated doped silicon first used in solar cells first spacecraft to use solar panels (Vanguard I) SERI begin operation first dual junction cell created NREL is established terrestrial PV shipments exceeds 50 MW % efficiency barrier broken National Center for Photovoltaics chartered terrestrial PV shipments exceed 100 MW terrestrial PV shipments exceeds 1 GW % efficiency barrier broken terrestrial PV shipments exceeds 10 GW

18 The Present

20 The history of PV and the history of NREL/SERI are synonymous. No other entity has played as significant a role in the tremendous technological development and creation of this exploding marketplace than NREL. It is estimated that without FSA, PVMat, TFP - PV costs would be 66% higher today. All 8 of the top PV companies in the U.S. have significant ties to NREL, as well as 9 out of the top 10 worldwide.

21 The U.S. has the best solar energy resource of any major industrialized nation on the Earth. Average insolation kwh/m 2 /day

22 3 TW

23 Solar Cell Efficiency inherent losses (i.e., solar photons with energies below the bandgap of the host material) η = solar cell efficiency J sc = short- circuit current V oc = open- circuit voltage FF = fill factor optical or electrical losses (i.e., reflectance, series resistance, etc.). J sc, V oc, and FF are intimately and fundamentally tied. It is difficult to affect one without changing the others.

24 Solar Constant (1 Sun = 1360 W/m 2 ) Air Mass Zero Standard Test Conditions (STC) Air Mass 1.5 (1000W/m 2, ASTM G and IEC ) at 25 o C

25 Solar Simulators Spectral match Irradiance inhomogeneity - spatial uniformity over the illumination area Temporal Instability - stability over time. 'A' is the top rating an 'C' is the lowest rating (IEC Ed. 2.0.)

26 1.45 ev Optimum PV Bandgap

27 III- V CIGS OPV

28 New records just achieved for III-V, CIGS, OPV, and CZTS III-V MJ rate of improvement has been ~ 1%/year III-V CIGS OPV CIGS has been increasing at about ~0.3%/year OPV is approaching 10% and improving at about 0.8%/ year New thin film material CZTS has achieved 10%

29 10% 20% 30% 40% 3.6 TW US Consumption

30 23,889 MW Worldwide PV production grew by > 100% in 2010!

33 PV prices have been in free-fall over past couple of years. Large differences in utility scale versus commercial rooftop and residential. Reasons: Efficiency Increases Economies of Scale Increased Competition

35 ~ 80% of PV production is in Asia ~ 80% of deployment is in Europe

38 Solar Advisor Model with real inputs (i.e., South facing, 25 degree fixed Dlt,4.3 kw DC system size, Local, state, and federal incendves as of October 2010, and the PV system financed as part of a 30 year home loan)

39 25 Year 80% BOL warrantees are the industry standard. <1% degradation/year Arrays installed after 2000 have been much more reliable, especially in the case of thin films.

40 The Future Making predictions is very hard... especially about the future.

41 No one size will fit all Silicon will continue to dominate in the near term, but thin films and concentrated photovoltaics will gain ground New economic models will emerge

42 Building Integrated Photovoltaics 85kW Shell Solar CIGS in Wales In Southern California 216 Würth CIGS modules in Tübingen, Germany

43 Concentrating Photovoltaics Inverted Metamorphic III-V Solar Cell > 40% Efficient

44 Roll-to-roll Thin Films

45 $5/WaX Cash purchase. Includes all Federal, state, and local (udlity) incendves, as of Q State average retail electricity rates. Principal Analyst: Sean Ong, NREL SEAC

46 $1/Watt Cash purchase. Unsubsidized. State average retail electricity rates. Note: Change to legend from previous slide. Principal Analyst: Sean Ong, NREL SEAC

48 Markup on all materials (module, inverter, BoS) included in Installer Overhead & Profit ResidenDal $0.89/W DC, Commercial $0.55, UDlity (fixed) $0.31 Reflects inventory costs (interest during construcdon), condngency

49 550 Module Price: $/Sq.Meter $1.00/Wp ac PV System: Target for Module Price is $0.50/Wp CdTe CIGS Si $2.00/Wp $1.50/Wp $1.00/Wp $0.50/Wp Module Efficiency

50 Economical Raw materials use % More abundant Materials (less In, Au, Ag) Manufacturability (low temp, non-vac, R2R) Low cost flexible substrates Cell efficiency Durability Environmentally Safe Non-toxic alternatives (less Cd, Te, Se) Aqueous based materials (less solvents) Re-use, Reman, Recycle Societal Reliability Building Integrated (BIPV) All these issues grow with success. Perhaps not big issues now, but to achieve large scale grid penetra9on (TW levels). A vision of the future should include high rate, high volume manufacturing using Earth abundant and benign materials.

51 Thank You