Large cubic tin sulfide–tin selenide thin film stacks for energy conversion

Large cubic (CUB) polymorphs of SnS and SnSe were identified in nanocrystals and in thin films during 2015–16. We present how thin films of SnS-CUB and SnSe-CUB can be stacked in different sequences to thickness of 450nm by chemical deposition. Grazing incidence X-ray diffraction pattern of the film...

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Bibliographic Details
Published in:Thin solid films 2016-09, Vol.615, p.415-422
Main Authors: Barrios-Salgado, Enue, Rodríguez-Guadarrama, Luis Alberto, Garcia-Angelmo, Ana Rosa, Campos Álvarez, José, Nair, M.T.S., Nair, P.K.
Format: Article
Language:English
Subjects:
Coefficients
Cubic tin selenide
Cubic tin sulfide
Current density
Diffraction patterns
Electrical properties
Grazing incidence
Heating
Optical properties
SnS
SnSe
Solar cells
Solar energy
Stacks
Thermoelectric conversion
Thermoelectricity
Thin films
Tin sulfide selenide thin films
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Summary:Large cubic (CUB) polymorphs of SnS and SnSe were identified in nanocrystals and in thin films during 2015–16. We present how thin films of SnS-CUB and SnSe-CUB can be stacked in different sequences to thickness of 450nm by chemical deposition. Grazing incidence X-ray diffraction pattern of the films establishes how these stacks of materials with a lattice constant a=11.59Å for SnS-CUB and 11.96Å for SnSe form, upon heating at 300°C, composite layers of SnS-CUB+SnS0.75Se0.25-CUB+SnSe-CUB. The layers so formed have optical band gap of nearly 1.52eV, intermediate to that of SnSe-CUB and SnS-CUB, of 1.38 and 1.73eV, respectively. With optical absorption coefficient exceeding 105cm−1 in the visible region, the stacks would produce light generated current density of 28–31mA/cm2 in solar cells for air mass 1.5 global solar radiation. Electrical conductivity of 0.01Ω−1cm−1, and Seebeck coefficient of up to 0.48mV/K of the layers suggest their possible application in thermoelectric converters as well. •Large cubic tin sulfide and tin selenide thin films are stacked via chemical deposition.•When heated, the stacks produce solid solutions of SnS-Se-CUB.•Such stacks have optical band gap 1.5eV and electrical conductivity 0.01Ω−1cm−1.•They are promising materials for solar cells and thermoelectric conversion.
ISSN:0040-6090
1879-2731
DOI:10.1016/j.tsf.2016.07.048