solar cells: current status and future prospects naveen khandelwal 2008ph10628
TRANSCRIPT
Solar Cells: Current status and Future prospects
Naveen Khandelwal2008PH10628
History “Photovoltaic effect” was first recognized in 1839 by
French physicist A. E. Becquerel.First photovoltaic cell was built, by Charles Fritts,
semiconductor selenium coated with an extremely thin layer of gold ;1% efficient.1883
Modern photovoltaic cell was developed at Bell Laboratories, 1954, using a diffused silicon p-n junction.
Space satellite use only. (crystalline Si, solar cells with efficiency of 6–10%) cost >$250per watt.
Cost reduction only due to semiconductor industry growth.$100 per watt in 1971.
Cont.SPC, New Jersey ,$20 per watt , Elliot Berman.1973o “reject” Si from Existing manufacturers ,very low cost.1970s-80s, solar powered Navigation Buoy as Natural market.o Automatic Power (Battery manufacturer) buys solar cell design rights
and suppressed to save battery market.o Tideland Signalo Increase in offshore oil platform, o “1973 oil crisis", Major oil giants (ARCO, EXXON, SHELL) came into
solar market.o Technology companies like GE,IBM,Motorola,Tyco etc.
Some termsPrice per watt: Total capital cost by the amount of peak
power can be produced.Grid parity:is the point at which alternative means of
generating electricity is at least as cheap as conventional grid power
Balance of system(BOS):all components of a photovoltaic system other than the photovoltaic panels like wiring, support rack, switches, inverter and batteries.
Current Capacity In 2010, Installed PV capacity was 40GW ,producing
50TWh of electricity every year. Growth rate of PV market is around 40%.EU leads the way with almost 30 GW as of 2010. Japan (3.6GW),the USA(2.5GW). India has merely 10MW PV capacity.c-Si and pc-Si wafers are the main materials.80%
Module prices are in the range of $3.0–4.5/Wp, and the system prices are in the range of $5–7/Wp, depending on technology and size.
Global Top 10 Solar Cell Manufacturer(2011)
Company Capacity (MW) Country
Suntech 2,400 China
JA Solar 2,100 China
Trina 1,900 China
Yingli 1,700 China
Motech 1,500 Taiwan
Gintech 1,500 Taiwan
Canadian Solar 1,300 China
Neo Solar Power 1,300 Taiwan
Hanwha Solar One 1,100 China
JinkoSolar 1,100 China
Top 10 thin-film Solar cell manufacturers(2011)
Thin films represented 16.8% of total global production.
1100.0 MW First Solar
123.4 MW Suntech solar
94.0 MW Sharp
60.0 MW HELIOSPHERA
60.0 MW Sungen Solar
50.0 MW Trony
43.0 MW Solar Frontier
42.0 MW Mitsubishi
40.0 MW Kaneka
40.0 MW vtech solar
Thermodynamic Efficiency Limits
Classic thermodynamic efficiency for a single homo junction cell is ~31% ,limited by transmission loss for photons below band gap and thermal relaxation loss for above band gap.1961(Shockley and Queisser model)
Quantum efficiency >1 in SW range of a-Si solar cell explained by Auger mechanism.
increase the power conversion efficiency of solar cells,1. tandem cells, (68.5 % theoretical)
2. impurity-band and intermediate-band devices,(as high as 63.2%)
3. hot-electron extraction, (66%)
4. carrier multiplication, (44.7% to 85.9%)
the so-called “third generation” PV.
Silicon solar cellsC-Si solar cell:• boron-doped single-crystal wafers (around 400µm thick) grown by
the Czochralski (CZ) process.
• residual impurities such as oxygen, carbon, and transition-metal ions.
• Oxygen reacts with the boron to form an electronically active defect.
• Si grown by the float-zone(FZ) process ,has lowest recombination losses.
• Si cell efficiencies close to 25% have been achieved.
• improved contact and surface passivation of the cell, along the front and rear surfaces, as well as an improved understanding of the significant role of light-trapping in Si devices
• Commercial c-Si cells have efficiencies in the range of 15–22%.
P-Si Solar cell:• reactive-ion etching, this process allows about a 40%
relative increase in absorption.• Bulk hydrogenation and nitride passivation of the cell
surface have produced good results.• Commercial pc-Si cells have efficiencies of 12–15%.
Thin Film Solar CellThin a-Si:H Films :
◦ Hydrogen passivation of dangling bonds.
◦ collection of current by having very thin n- and p-layers, with an intrinsic intermediate layer.
◦ Intrinsic layer degrade under illumination, because Si-H bonds are destroyed under visible light.
◦ 8–10% of the worldwide PV production uses a-Si technology.
◦ Deposition technique: Silane (SiH4) based PECVD and glow discharge CVD
◦ around 10% dilution with hydrogen ,deposition rate 3A0/s.
◦ Efficiency,6% for single-junction a-Si up to 9% to 10% for commercial high-performance micromorph modules
a-Si:H Configuration
commercial thin-film silicon PV modules by developer
CdTe thin film modules
Direct band gap, ~1.45ev bandgap quite favorable. In 2009, commercial CdTe module sales surpassed 1,000 MW.production costs of $0.76/Wp.Starting with a TCO-coated glass(SnOx:F)
the (CdS) and CdTe layers are sequentially added via a vapor-transport deposition or closed-space sublimation process
The CdTe active layer is then treated at 400 °C to 450 °C in a CdCl2 atmosphere.
After which a carbon-based paste containing Cu is added and annealed before the final backside Al electrode is added.
Commercial CdTe PV module Developer
CIGS solar modules
20% (the highest value for thin-film cells) on a CIGS cell was achieved at NREL.
Commercial efficiency ~10%.band gap of CIGS can be varied continuously between
1.04 and 1.68 eV.Different techniques for growth of active layer o Co-evaporation of Cu,In,Ga in Se environment oRF sputtering then selenization around(450-5500C)oReactive sputteringoElectrochemical deposition
Commercial (CIGS) PV modules by developer
Organic photovoltaics (OPV) and dye-sensitized solar cell (DSSC)newest entrants to the commercial PV product market.DSSCs based on liquid electrolytes have reached
efficiencies as high as 10% under AM 1.5OPV conversion efficiency ~1%.
Schematic of OPV and DSSC
Terrestrial Solar cell efficiency atAM1.5 at 25 oC
Classification Efficiency Fill factor
Si (Crystalline) 25.0+/-0.5 82.8
Poly-Si 20.4+/-0.5 80.9
Thin film-Si 16.7+/-0.4 78.2
Thin film-GaAs 27.6+/-0.8 84.1
CIGS 19.6+/-0.6 79.2
CdTe 12.5+/-0.4 70.5
a-Si 10.1+/-0.3 67
DSSC 10.4+/-0.3 65.2
Organic (Polymer)
8.3+/-0.3 70.2
GaInP/GaAs/Ge 32.5+/-1.5 85
a-Si/µcSi 11.9+/-0.8 68.5
Organic (2 tandem)
8.3+/-0.3 59.5
References“Solar photovoltaic electricity: Current status and future
prospects” :T.M. Razykov , C.S. Ferekides , D. Morel , E. Stefanakos b, H.S. Ullal ,H.M. Upadhyaya, 2010
“Commercial status of thin-film photovoltaic devices and materials” :Johanna Schmidtke, 2010.
EPIA :Global market outlook for phtovoltaics,2010“Solar cell efficiency tables” :Martin A. Green, Keith Emery,
Yoshihiro Hishikawa and Wilhelm Warta, Oct, 2010