Physical properties of the absorber layer Sn2Sb2S5 thin films for photovoltaics

N. Ali; A. Hussain; S. T. Hussain; M. A. Iqbal; M. Shah; I. Rahim; N. Ahmad; Z. Ali; K. Hutching; D. Lane; W. A.A. Syed

doi:10.2174/157341313805117794

Physical properties of the absorber layer Sn₂Sb₂S₅ thin films for photovoltaics

N. Ali^*, A. Hussain, S. T. Hussain, M. A. Iqbal, M. Shah, I. Rahim, N. Ahmad, Z. Ali, K. Hutching, D. Lane, W. A.A. Syed

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

Tin antimony sulphide thin films have been deposited on glass substrate by thermal evaporation technique at a chamber pressure of 10^-4 torr. For the characterization purpose, thin films were deposited and annealed in argon gas at 100 °C, 150 °C and 250 °C. The physical properties of the films have been inspected relating annealing temperature. XRD studies revealed that both the as deposited and annealed films exist in Sn₂Sb₂S₅ phase. The absorption coefficient of the annealed films was found to be ~10⁵ cm^-1. Photoconductivity response of these films was also fine and enhanced with the increasing temperature. However, the transmittance of the films investigated was quite low. No transmittance was found below 750 nm which decreased with annealing temperature. The band gap calculated by ellipsometry technique was in the range 2.5-1.6 eV. Thickness of the film was observed as 1450 nm and the films possess n-type conductivity.

Original language	English
Pages (from-to)	149-152
Number of pages	4
Journal	Current Nanoscience
Volume	9
Issue number	1
DOIs	https://doi.org/10.2174/157341313805117794
State	Published - 2013
Externally published	Yes

Keywords

Absorption coefficient
Band gap
Photovoltaics
Transmittance

ASJC Scopus subject areas

Biotechnology
Bioengineering
Medicine (miscellaneous)
Biomedical Engineering
Pharmaceutical Science

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.2174/157341313805117794

Cite this

@article{56fcdc1f20a04f62a2c658ee826fb3fc,

title = "Physical properties of the absorber layer Sn2Sb2S5 thin films for photovoltaics",

abstract = "Tin antimony sulphide thin films have been deposited on glass substrate by thermal evaporation technique at a chamber pressure of 10-4 torr. For the characterization purpose, thin films were deposited and annealed in argon gas at 100 °C, 150 °C and 250 °C. The physical properties of the films have been inspected relating annealing temperature. XRD studies revealed that both the as deposited and annealed films exist in Sn2Sb2S5 phase. The absorption coefficient of the annealed films was found to be \textasciitilde{}105 cm-1. Photoconductivity response of these films was also fine and enhanced with the increasing temperature. However, the transmittance of the films investigated was quite low. No transmittance was found below 750 nm which decreased with annealing temperature. The band gap calculated by ellipsometry technique was in the range 2.5-1.6 eV. Thickness of the film was observed as 1450 nm and the films possess n-type conductivity.",

keywords = "Absorption coefficient, Band gap, Photovoltaics, Transmittance",

author = "N. Ali and A. Hussain and Hussain, \{S. T.\} and Iqbal, \{M. A.\} and M. Shah and I. Rahim and N. Ahmad and Z. Ali and K. Hutching and D. Lane and Syed, \{W. A.A.\}",

year = "2013",

doi = "10.2174/157341313805117794",

language = "English",

volume = "9",

pages = "149--152",

journal = "Current Nanoscience",

issn = "1573-4137",

publisher = "Bentham Science Publishers",

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TY - JOUR

T1 - Physical properties of the absorber layer Sn2Sb2S5 thin films for photovoltaics

AU - Ali, N.

AU - Hussain, A.

AU - Hussain, S. T.

AU - Iqbal, M. A.

AU - Shah, M.

AU - Rahim, I.

AU - Ahmad, N.

AU - Ali, Z.

AU - Hutching, K.

AU - Lane, D.

AU - Syed, W. A.A.

PY - 2013

Y1 - 2013

N2 - Tin antimony sulphide thin films have been deposited on glass substrate by thermal evaporation technique at a chamber pressure of 10-4 torr. For the characterization purpose, thin films were deposited and annealed in argon gas at 100 °C, 150 °C and 250 °C. The physical properties of the films have been inspected relating annealing temperature. XRD studies revealed that both the as deposited and annealed films exist in Sn2Sb2S5 phase. The absorption coefficient of the annealed films was found to be ~105 cm-1. Photoconductivity response of these films was also fine and enhanced with the increasing temperature. However, the transmittance of the films investigated was quite low. No transmittance was found below 750 nm which decreased with annealing temperature. The band gap calculated by ellipsometry technique was in the range 2.5-1.6 eV. Thickness of the film was observed as 1450 nm and the films possess n-type conductivity.

AB - Tin antimony sulphide thin films have been deposited on glass substrate by thermal evaporation technique at a chamber pressure of 10-4 torr. For the characterization purpose, thin films were deposited and annealed in argon gas at 100 °C, 150 °C and 250 °C. The physical properties of the films have been inspected relating annealing temperature. XRD studies revealed that both the as deposited and annealed films exist in Sn2Sb2S5 phase. The absorption coefficient of the annealed films was found to be ~105 cm-1. Photoconductivity response of these films was also fine and enhanced with the increasing temperature. However, the transmittance of the films investigated was quite low. No transmittance was found below 750 nm which decreased with annealing temperature. The band gap calculated by ellipsometry technique was in the range 2.5-1.6 eV. Thickness of the film was observed as 1450 nm and the films possess n-type conductivity.

KW - Absorption coefficient

KW - Band gap

KW - Photovoltaics

KW - Transmittance

UR - https://www.scopus.com/pages/publications/84875931077

U2 - 10.2174/157341313805117794

DO - 10.2174/157341313805117794

M3 - Article

AN - SCOPUS:84875931077

SN - 1573-4137

VL - 9

SP - 149

EP - 152

JO - Current Nanoscience

JF - Current Nanoscience

IS - 1

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