Solar cells copper indium diselenide

Selenium is also used in thin-film photovoltaic cells (qv) which contain copper indium diselenide [12018-95-0] CuInSe2. Use is quite small as of 1996. However, if the United States solar energy output with such cells were to increase by 100 MW/yr, this would require 8 t of selenium aimuaHy (see... 

Basol, B. M. Kapur, V. K. Leidholm, C. R. Halani, A. 1996. Flexible and light weight copper indium diselenide solar cells. Conference Record of the Twenty-Fifth IEEE Photovoltaic Specialists Conference (NREL Report No. TP-410-21091), pp. 157-162. 

Abou-Elfotouh, F. A. Moutinho, FI. Bakry, A. Coutts, T. J. Kazmerski, L. L. 1991. Characterization of the defect levels in copper indium diselenide. Solar Cells 30 151-160. 

Thin Film - A layer of semiconductor material, such as copper indium diselenide or gallium arsenide, a few microns or less in thickness, used to make solar photovoltaic cells. 

Theoretical conversion efficiencies of photovoltaic systems depend on the semiconductor materials used in the cells and on the ambient tanperatuie. The materials currently used to make photovoltaic cells can be grouped into three broad categories 1) expensive, efficient monocrystalline silicon, 2) less efficient but much lower cost polycrystalline silicon, and 3) the lowest cost and poorest performer, amorphous silicon material. Conversion efficiencies of commercial polycrystaUine silicon cells are 10 to 15 percent. Now the primary development areas are in how to use monocrystalline silicon with solar concentrators and making thin-film cells by depositing a 5- to 20-micron film of silicon onto an inexpensive substrate, because the estimated efficiency of these cells is above 20 percent. Work is ongoing with other materials, including amorphous silicon (a-Si), copper indium diselenide (CuInSe2 or CIS) and related materials, and cadmium telluride (CdTe). 

FIGURE 7.2 Thin copper indium diselenide solar cell. Progress in manufacturing is mostly empirical, with little understanding of material properties, devices, and processes that lead to higher efficiency. 

The deposition of CBD CdS as a junction layer for solar cell devices has proven to be a very successful industrially acceptable technique. Kessler et al.13 reported on copper indium gallium diselenide (CIGS) mini-modules (area = 16cm2) with a conversion efficiency of 16.6%, wherein CBD CdS was used as a junction layer. Basol et al.14 fabricated 9.3% active-area efficient thin-film flexible CuInSe2 (CIS) solar cells (specific power >1 kW/kg) on lightweight, flexible metallic, and polymeric (polymide-based) substrates using CBD CdS. 

Single crystal silicon (sc-Si), polyciystalline silicon (p-Si), and amorphous silicon (a-Si) can all be used to make solar cells, with fabrication cost and device photoconversion efficiencies decreasing as one moves from single-crystal to amorphous materials. Various properties of these materials are summarized in Table 8.1. Other relatively common solar cell materials include gallium arsenide (GaAs), copper indiirm diselenide (CIS), copper indium-gallium... 

Abstract Photovoltaic cells have been dominated so far by solid state p-n junction devices made from silicon or gallium arsenide wavers or thin film embodiments based on amorphous silicon, CdTe and copper indium gallium diselenide (CIGS) profiting from the experience and material availability of the semiconductor industry. Recently there has been a surge of interest for devices that are based on nanoscale inorganic or organic semiconductors commonly referred to as bulk junctions due to their interconnected three-dimensional structure. The present chapter describes the state of the art of the academic and industrial development of nanostructured solar cells, with emphasis in the development of the dye-sensitized nanocristalline solar cell. 

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