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Main Authors: Huang, Yi-Teng, Wang, Yixin, Fields, Georgia, Cong, Peixi, Wang, Yongjie, Swallow, Jack E. N., Roy, Avari, Woolley, Jack M., Rotaru, Victoria, Guc, Maxim, van Turnhout, Lars, Aouane, Mohamed, Suard, Emmanuelle, Kubicki, Dominik, Pérez-Rodríguez, Alejandro, Sadhanala, Aditya, Rao, Akshay, Friedrich, Dennis, Weatherup, Robert S., Clarke, Simon J., Kavanagh, Seán R., Hoye, Robert L. Z.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.22024
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author Huang, Yi-Teng
Wang, Yixin
Fields, Georgia
Cong, Peixi
Wang, Yongjie
Swallow, Jack E. N.
Roy, Avari
Woolley, Jack M.
Rotaru, Victoria
Guc, Maxim
van Turnhout, Lars
Aouane, Mohamed
Suard, Emmanuelle
Kubicki, Dominik
Pérez-Rodríguez, Alejandro
Sadhanala, Aditya
Rao, Akshay
Friedrich, Dennis
Weatherup, Robert S.
Clarke, Simon J.
Kavanagh, Seán R.
Hoye, Robert L. Z.
author_facet Huang, Yi-Teng
Wang, Yixin
Fields, Georgia
Cong, Peixi
Wang, Yongjie
Swallow, Jack E. N.
Roy, Avari
Woolley, Jack M.
Rotaru, Victoria
Guc, Maxim
van Turnhout, Lars
Aouane, Mohamed
Suard, Emmanuelle
Kubicki, Dominik
Pérez-Rodríguez, Alejandro
Sadhanala, Aditya
Rao, Akshay
Friedrich, Dennis
Weatherup, Robert S.
Clarke, Simon J.
Kavanagh, Seán R.
Hoye, Robert L. Z.
contents Ag(I)-Bi(III)-based semiconductors have gained substantial attention as nontoxic, stable alternatives to lead-halide perovskites for optoelectronics, but are widely limited by carrier localization, which severely restricts diffusion lengths. The most efficient Ag/Bi solar absorber is AgBiS2, but diffusion lengths in nanocrystal films are <50 nm. Carrier localization in this rock-salt (Fm-3m) system is believed to arise from cation disorder, and so we herein investigate the layered cation-ordered analogue. Through beyond-DFT simulations combined with neutron and X-ray powder diffraction, we reveal that off-centring of Ag+ and Bi3+ cations is energetically-favoured in this cation-ordered phase. Despite local distortions in the AgS6 and BiS6 octahedra, band-like transport takes place, which, surprisingly, also occurs in the cation-disordered rock-salt phase when these materials are made as bulk powders. The cubic-phase powders have the same degree of cation disorder as the nanocrystals that have carrier localization, which suggests that extrinsic factors play a determining role. We ascribe the intrinsic band-like transport of both phases of AgBiS2 to its close packing, ensuring high electronic dimensionality. These insights offer pathways for designing solar absorbers avoiding carrier localization limitations, and call for future efforts to enhance the efficiency of AgBiS2 photovoltaics to focus on large-grained thin films, or improved nanocrystal surface passivation.
format Preprint
id arxiv_https___arxiv_org_abs_2602_22024
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Band-Like Transport and Cation Off-Centring in Ag/Bi-Based Solar Absorbers
Huang, Yi-Teng
Wang, Yixin
Fields, Georgia
Cong, Peixi
Wang, Yongjie
Swallow, Jack E. N.
Roy, Avari
Woolley, Jack M.
Rotaru, Victoria
Guc, Maxim
van Turnhout, Lars
Aouane, Mohamed
Suard, Emmanuelle
Kubicki, Dominik
Pérez-Rodríguez, Alejandro
Sadhanala, Aditya
Rao, Akshay
Friedrich, Dennis
Weatherup, Robert S.
Clarke, Simon J.
Kavanagh, Seán R.
Hoye, Robert L. Z.
Materials Science
Ag(I)-Bi(III)-based semiconductors have gained substantial attention as nontoxic, stable alternatives to lead-halide perovskites for optoelectronics, but are widely limited by carrier localization, which severely restricts diffusion lengths. The most efficient Ag/Bi solar absorber is AgBiS2, but diffusion lengths in nanocrystal films are <50 nm. Carrier localization in this rock-salt (Fm-3m) system is believed to arise from cation disorder, and so we herein investigate the layered cation-ordered analogue. Through beyond-DFT simulations combined with neutron and X-ray powder diffraction, we reveal that off-centring of Ag+ and Bi3+ cations is energetically-favoured in this cation-ordered phase. Despite local distortions in the AgS6 and BiS6 octahedra, band-like transport takes place, which, surprisingly, also occurs in the cation-disordered rock-salt phase when these materials are made as bulk powders. The cubic-phase powders have the same degree of cation disorder as the nanocrystals that have carrier localization, which suggests that extrinsic factors play a determining role. We ascribe the intrinsic band-like transport of both phases of AgBiS2 to its close packing, ensuring high electronic dimensionality. These insights offer pathways for designing solar absorbers avoiding carrier localization limitations, and call for future efforts to enhance the efficiency of AgBiS2 photovoltaics to focus on large-grained thin films, or improved nanocrystal surface passivation.
title Band-Like Transport and Cation Off-Centring in Ag/Bi-Based Solar Absorbers
topic Materials Science
url https://arxiv.org/abs/2602.22024