The electronic structure of the antimony chalcogenide series: Prospects for optoelectronic applications

Carey, John J.; Allen, Jeremy P.; Scanlon, David O.; Watson, Graeme W.

doi:10.1016/j.jssc.2014.02.014

Cited by 93 publications

(74 citation statements)

References 111 publications

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“…The bandgaps obtained are in accordance with an E g of 1.55–1.72 eV reported for Sb 2 S 3 films deposited by spray pyrolysis [48]. Theoretical calculations predict an even lower direct optical transition of 1.40 eV [49]. An absorber bandgap of 1.65 eV is found in solar cells with Sb 2 S 3 prepared by ALD [5,19] or in solar cells with Sb 2 S 3 prepared by CBD, as estimated from the photocurrent edge at around 750 nm in the published EQE plots [2,4,6–9 11–12 15–17 40–41 50–53].…”

Section: Resultssupporting

confidence: 83%

Sb₂S₃ grown by ultrasonic spray pyrolysis and its application in a hybrid solar cell

Kärber¹,

Katerski²,

Açik³

et al. 2016

Beilstein J. Nanotechnol.

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Chemical spray pyrolysis (CSP) is a fast wet-chemical deposition method in which an aerosol is guided by carrier gas onto a hot substrate where the decomposition of the precursor chemicals occurs. The aerosol is produced using an ultrasonic oscillator in a bath of precursor solution and guided by compressed air. The use of the ultrasonic CSP resulted in the growth of homogeneous and well-adhered layers that consist of submicron crystals of single-phase Sb2S3 with a bandgap of 1.6 eV if an abundance of sulfur source is present in the precursor solution (SbCl3/SC(NH2)2 = 1:6) sprayed onto the substrate at 250 °C in air. Solar cells with glass-ITO-TiO2-Sb2S3-P3HT-Au structure and an active area of 1 cm2 had an open circuit voltage of 630 mV, short circuit current density of 5 mA/cm2, a fill factor of 42% and a conversion efficiency of 1.3%. Conversion efficiencies up to 1.9% were obtained from solar cells with smaller areas.

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Section: Resultssupporting

confidence: 83%

Sb₂S₃ grown by ultrasonic spray pyrolysis and its application in a hybrid solar cell

Kärber¹,

Katerski²,

Açik³

et al. 2016

Beilstein J. Nanotechnol.

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show abstract

“…[28], and with experimental values of 0.11 eV 29 and 0.16 eV 30,31 . Our computed band gap R3m-E g,Sb2T e3 is larger than another one also calculated with VASP of 0.09 eV 32 , however, somewhat closer to the experimental range from 0.29 to 0.46 eV 33,34 . In all scenarios, Bi, Sb and Te s states lie below -6 eV in the valence band.…”

Section: Resultssupporting

confidence: 74%

Efficient technique for computational design of thermoelectric materials

Núñez-Valdez

Allahyari

Fan

et al. 2018

Computer Physics Communications

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Efficient thermoelectric materials are highly desirable, and the quest for finding them has intensified as they could be promising alternatives to fossil energy sources. Here we present a general first-principles approach to predict, in multicomponent systems, efficient thermoelectric compounds. The method combines a robust evolutionary algorithm, a Pareto multiobjective optimization, density functional theory and a Boltzmann semi-classical calculation of thermoelectric efficiency. To test the performance and reliability of our overall framework, we use the well-known system Bi2Te3-Sb2Te3.

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“…4 The VB top is comprising from Se 4p lone‐pair ( lp ) states, whereas CB bottom is described as coming from Ge 4s ‐Se 4p anti‐bonding states . Moreover, according Carey et al, in Sb 2 Se 3 the VB is comprised of Sb 5s / p with a contribution from Se 4p states, based on the DFT calculation. According to XPS data published by Sati et al for bulk Ge 40‐x Sb x Se 60 (x = 8, 20) glasses, the peaks in the spectra ascribed to Se lp electron states and Sb 5p bonding electrons in Sb–Sb bonds are found at the very top of the valence band.…”

Section: Resultsmentioning

confidence: 99%

Amorphous Ge‐Sb‐Se thin films fabricated by co‐sputtering: Properties and photosensitivity

et al. 2018

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Amorphous Ge–Sb–Se thin films were fabricated by a rf‐magnetron co‐sputtering technique employing the following cathodes: GeSe2, Sb2Se3, and Ge28Sb12Se60. The influence of the composition, determined by energy‐dispersive X‐ray spectroscopy, on the optical properties was studied. Optical properties were analyzed based on variable angle spectroscopic ellipsometry and UV‐Vis‐NIR spectrophotometry. The results show that the optical bandgap range 1.35‐2.08 eV with corresponding refractive index ranging from 3.33 to 2.36 can be reliably covered. Furthermore, morphological and topographical properties of selenide‐sputtered films studied by scanning electron microscopy and atomic force microscopy showed a good quality of fabricated films. In addition, structure of the films was controlled using Raman scattering spectroscopy. Finally, irreversible photoinduced changes by means of change in optical bandgap energy and refractive index of co‐sputtered films were studied revealing the photobleaching effect in Ge‐rich films when irradiated by near‐bandgap light under Ar atmosphere. The photobleaching effect tends to decrease with increasing antimony content.

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The electronic structure of the antimony chalcogenide series: Prospects for optoelectronic applications

Cited by 93 publications

References 111 publications

Sb₂S₃ grown by ultrasonic spray pyrolysis and its application in a hybrid solar cell

Sb₂S₃ grown by ultrasonic spray pyrolysis and its application in a hybrid solar cell

Efficient technique for computational design of thermoelectric materials

Amorphous Ge‐Sb‐Se thin films fabricated by co‐sputtering: Properties and photosensitivity

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The electronic structure of the antimony chalcogenide series: Prospects for optoelectronic applications

Cited by 93 publications

References 111 publications

Sb2S3 grown by ultrasonic spray pyrolysis and its application in a hybrid solar cell

Sb2S3 grown by ultrasonic spray pyrolysis and its application in a hybrid solar cell

Efficient technique for computational design of thermoelectric materials

Amorphous Ge‐Sb‐Se thin films fabricated by co‐sputtering: Properties and photosensitivity

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Product

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Sb₂S₃ grown by ultrasonic spray pyrolysis and its application in a hybrid solar cell

Sb₂S₃ grown by ultrasonic spray pyrolysis and its application in a hybrid solar cell