2014
DOI: 10.1002/adfm.201402288
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All Solution‐Processed Chalcogenide Solar Cells – from Single Functional Layers Towards a 13.8% Efficient CIGS Device

Abstract: Solution processing of inorganic thin fi lms has become an important thrust in material research community because it offers low-cost and high-throughput deposition of various functional coatings and devices. Especially inorganic thin fi lm solar cells -macroelectronic devices that rely on consecutive deposition of layers on large-area rigid and fl exible substrates -could benefi t from solution approaches in order to realize their low-cost nature. This article critically reviews existing deposition approaches… Show more

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Cited by 92 publications
(64 citation statements)
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References 163 publications
(214 reference statements)
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“…The reason for this is that the often-used optical transmittance is strongly linked to the reflectance of the transparent electrode, which, in turn, is strongly influenced by the optical properties of the substrate, the film thickness, and the surface texture. In addition, while the transmittance is normally measured on a flat glass substrate, several solar cell absorbers feature textured surfaces (e.g., silicon heterojunction solar cells [1] ) or randomly oriented grains (e.g., CIGS and CZTS [107] ), which increase the roughness of the films and influence the reflectance of the layered stacks. To make an accurate and fair comparison of the amount of light that is parasitically absorbed by a transparent electrode, independent of the substrate and surface roughness, we therefore use the absorptance (A) value, defined as A = 1 -TT -TR, where TT is the total transmittance and TR is the total reflectance.…”
Section: Classification Of Transparent Electrodes According To the Rementioning
confidence: 99%
“…The reason for this is that the often-used optical transmittance is strongly linked to the reflectance of the transparent electrode, which, in turn, is strongly influenced by the optical properties of the substrate, the film thickness, and the surface texture. In addition, while the transmittance is normally measured on a flat glass substrate, several solar cell absorbers feature textured surfaces (e.g., silicon heterojunction solar cells [1] ) or randomly oriented grains (e.g., CIGS and CZTS [107] ), which increase the roughness of the films and influence the reflectance of the layered stacks. To make an accurate and fair comparison of the amount of light that is parasitically absorbed by a transparent electrode, independent of the substrate and surface roughness, we therefore use the absorptance (A) value, defined as A = 1 -TT -TR, where TT is the total transmittance and TR is the total reflectance.…”
Section: Classification Of Transparent Electrodes According To the Rementioning
confidence: 99%
“…[ 6,7 ] The attractiveness of these materials lies in their high extinction coeffi cients, large minority-carrier diffusion lengths (few micrometers), easily tunable band-gap energy (1.0-2.4 eV) by adjusting the alloy composition, and well-positioned conduction band for water photoreduction. In contrast to the PV fi eld-which has focused mainly on the Se-based chalcopyrites-the S-based analogs are better suited to PEC application due to their lower toxicity, the larger relative abundance of sulfur, their improved stability in aqueous electrolytes, and their wider band gap energy.…”
Section: Introductionmentioning
confidence: 99%
“…Chalcogenide glasses (ChGs) are an important class of materials used in phase-change memories [1], solar cells [2], sensors [3] and photonics [4]. They contain as their main constituent one or more of the chalcogen elements S, Se and Te, covalently bonded to network formers such as As, Ge, Sb, Ga, Si or P [4,5].…”
Section: Introductionmentioning
confidence: 99%