Übersicht
Solar cells of 1st, 2nd and 3rd generation
1st: Solar cells (today 95% of the world market)
made of polycrystalline or monocrystalline
silicon (indirect semiconductor), cells are
connected to form modules.
2nd: Thin film solar cells (e.g. amorphous silicon,
CdTe, CIS, ...), direct semiconductors,
production by evaporation and direct structuring
to modules.
3rd: Solar cells with "photon management",
either multiple cells mechanically or
monolithically stacked on top of each other
with different band gaps or "photon
recycling" by up- or down conversion.
Percentage of global annual PV production by technology 2021
thin film 10 GWP
Multi-Si 20
Mono-Si 160
von thin: CdTe>CIGS>a-Si
amorphorous silicon
In contrast to crystalline silicon, a-si is a direct semiconductor.
Efficiency stabilizes itself during operation
CIGS Technology
■ Copper Indium Gallium Diselenide
■ Laboratory cell efficiency: 22.9%
■ Module efficiency: 14.5%
■ Advantages:
□ Environmentally friendly
□ Greater heat resistance
□ Long lifecycle
■ Disadvantage:
□ High manufacturing costs
CdTe Technology
■ Cadmium-Telluride
■ 43% Market share of thin-film PV
■ Laboratory cell efficiency: 22.1%
■ Module efficiency: 16.1%
□ Simple and cost-effective
manufacturing process
□ Cadmium ist abundant
□ Good low-light performance
□ Good temperature behaviour
■ Disadvantages:
□ Cadmium is toxic
□ Telluride is a rare material
CZTS Technology
■ Copper-Zinc-Tin sulphide
■ Laboratory cell efficiency: 12.6%
□ All materials used are non-toxic and
abundant
□ Low manufacturing costs
□ Low efficiency
□ Lack of knowledge of electrical and
chemical properties of the material
Comparison Semiconductor Absorber Material
Organic Solar Cells (OSC)
Photoactive material of organic molecules or conductive
polymers based on C-H
■ Donor acceptor system comprising a transparent
electrode (ITO) and a metallic counter electrode
Donator: CN-PPV, P3HT, MEH-PPV
■ Functions: light absorption, emission of an electron,
transport of the hole to the cathode
Acceptor: Fullerene C60, C70
■ Function: electron uptake and transport to the anode
■ Very thin cells (approx. 0.1μm)
OSC strucutre, pros, cons
OSC swat analysis
Dye Sensitised Solar Cells (DSSC)
■ Photo-electrochemical system, also called Grätzel cell
(name of the inventor)
■ Light absorption takes place in organic dyes
(e.g. ruthenium-based or chlorophyll)
■ Dyestuffs deposited on highly porous carrier material
(TiO2, ZnO, SnO2), resulting in increased effective
surface area
■ Good low-light performance
■ Efficiencies at 12% (cell) and 8% (module)
DSSC swot analysis
Multi-junction cells
Stacking two solar cells: Tandem cells
→ Efficiency is significantly increased
• Light is absorbed at different depths
depending on wavelength
• Cells connected in series: weaker cell
determines total current
Triple cells
Stabilized efficiencies of 38 % were achieved
Staebler-Wronski effect very low
Micromorph = microcrystalline + amorphous
Stable efficiencies Laboratory cells: 12%, modules: max. 10%
Energy Payback Times (Solar Roof Top , Germany)
Installed PV capacity worldwide (2005 – 2023)
Installed PV capacity in Germany (2002 – mid 2023)
Thin film technology
requires the least amount of energy for
production
semiconductor materials
Amorphous Silicon (a-Si)
Gallium Arsenide (GaAs)
Copper Indium Gallium Selenide (CIGS)
Cadmium Telluride (CdTe)
summary
Zuletzt geändertvor 14 Tagen
