Systematic Bandgap Engineering of a 2D Organic–Inorganic Chalcogenide Semiconductor via Ligand Modification

Tomoaki Sakurada; Watcharaphol Paritmongkol; Yeongsu Cho; Woo Seok Lee; Petcharaphorn Chatsiri; Julius J. Oppenheim; Ruomeng Wan; Annlin Su; Nicholas Samulewicz; Khemika Wannakan; Peter Müller; Mircea Dincă; Heather J. Kulik; William A. Tisdale

doi:10.1021/jacs.5c07989

Systematic Bandgap Engineering of a 2D Organic–Inorganic Chalcogenide Semiconductor via Ligand Modification

Tomoaki Sakurada, Watcharaphol Paritmongkol, Yeongsu Cho, Woo Seok Lee, Petcharaphorn Chatsiri, Julius J. Oppenheim, Ruomeng Wan, Annlin Su, Nicholas Samulewicz, Khemika Wannakan, Peter Müller, Mircea Dincă, Heather J. Kulik, William A. Tisdale

Chemistry

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

1 Scopus citations

Abstract

Hybrid organic–inorganic semiconductors present new opportunities for optoelectronic materials design not available in all-organic or all-inorganic materials. One example is silver phenylselenide (AgSePh) – or “mithrene” – a blue-emitting 2D organic–inorganic semiconductor exhibiting strong optical and electronic anisotropy. Here, we show that the bandgap of mithrene can be systematically tuned by introducing electron-donating and electron-withdrawing groups to the phenyl ligands. We synthesized nine mithrene variants, eight of which formed 2D van der Waals crystals analogous to those of AgSePh. Density functional theory calculations reveal that these 2D mithrene variants are direct-gap or nearly direct gap semiconductors. Furthermore, we identify correlations between the optical gap and three experimental observables – the Hammett constant,⁷⁷Se chemical shift, and selenium partial charge – offering predictive power for bandgap tuning. These findings highlight new opportunities for applying the tools of chemical synthesis to semiconductor materials design.

Original language	English (US)
Pages (from-to)	31704-31712
Number of pages	9
Journal	Journal of the American Chemical Society
Volume	147
Issue number	35
DOIs	https://doi.org/10.1021/jacs.5c07989
State	Published - Sep 3 2025

All Science Journal Classification (ASJC) codes

Catalysis
Biochemistry
General Chemistry
Colloid and Surface Chemistry

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Sakurada, T., Paritmongkol, W., Cho, Y., Lee, W. S., Chatsiri, P., Oppenheim, J. J., Wan, R., Su, A., Samulewicz, N., Wannakan, K., Müller, P., Dincă, M., Kulik, H. J., & Tisdale, W. A. (2025). Systematic Bandgap Engineering of a 2D Organic–Inorganic Chalcogenide Semiconductor via Ligand Modification. Journal of the American Chemical Society, 147(35), 31704-31712. https://doi.org/10.1021/jacs.5c07989

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title = "Systematic Bandgap Engineering of a 2D Organic–Inorganic Chalcogenide Semiconductor via Ligand Modification",

abstract = "Hybrid organic–inorganic semiconductors present new opportunities for optoelectronic materials design not available in all-organic or all-inorganic materials. One example is silver phenylselenide (AgSePh) – or “mithrene” – a blue-emitting 2D organic–inorganic semiconductor exhibiting strong optical and electronic anisotropy. Here, we show that the bandgap of mithrene can be systematically tuned by introducing electron-donating and electron-withdrawing groups to the phenyl ligands. We synthesized nine mithrene variants, eight of which formed 2D van der Waals crystals analogous to those of AgSePh. Density functional theory calculations reveal that these 2D mithrene variants are direct-gap or nearly direct gap semiconductors. Furthermore, we identify correlations between the optical gap and three experimental observables – the Hammett constant,77Se chemical shift, and selenium partial charge – offering predictive power for bandgap tuning. These findings highlight new opportunities for applying the tools of chemical synthesis to semiconductor materials design.",

author = "Tomoaki Sakurada and Watcharaphol Paritmongkol and Yeongsu Cho and Lee, \{Woo Seok\} and Petcharaphorn Chatsiri and Oppenheim, \{Julius J.\} and Ruomeng Wan and Annlin Su and Nicholas Samulewicz and Khemika Wannakan and Peter M{\"u}ller and Mircea Dinc{\u a} and Kulik, \{Heather J.\} and Tisdale, \{William A.\}",

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Sakurada, T, Paritmongkol, W, Cho, Y, Lee, WS, Chatsiri, P, Oppenheim, JJ, Wan, R, Su, A, Samulewicz, N, Wannakan, K, Müller, P, Dincă, M, Kulik, HJ & Tisdale, WA 2025, 'Systematic Bandgap Engineering of a 2D Organic–Inorganic Chalcogenide Semiconductor via Ligand Modification', Journal of the American Chemical Society, vol. 147, no. 35, pp. 31704-31712. https://doi.org/10.1021/jacs.5c07989

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AU - Sakurada, Tomoaki

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AU - Lee, Woo Seok

AU - Chatsiri, Petcharaphorn

AU - Oppenheim, Julius J.

AU - Wan, Ruomeng

AU - Su, Annlin

AU - Samulewicz, Nicholas

AU - Wannakan, Khemika

AU - Müller, Peter

AU - Dincă, Mircea

AU - Kulik, Heather J.

AU - Tisdale, William A.

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N2 - Hybrid organic–inorganic semiconductors present new opportunities for optoelectronic materials design not available in all-organic or all-inorganic materials. One example is silver phenylselenide (AgSePh) – or “mithrene” – a blue-emitting 2D organic–inorganic semiconductor exhibiting strong optical and electronic anisotropy. Here, we show that the bandgap of mithrene can be systematically tuned by introducing electron-donating and electron-withdrawing groups to the phenyl ligands. We synthesized nine mithrene variants, eight of which formed 2D van der Waals crystals analogous to those of AgSePh. Density functional theory calculations reveal that these 2D mithrene variants are direct-gap or nearly direct gap semiconductors. Furthermore, we identify correlations between the optical gap and three experimental observables – the Hammett constant,77Se chemical shift, and selenium partial charge – offering predictive power for bandgap tuning. These findings highlight new opportunities for applying the tools of chemical synthesis to semiconductor materials design.

AB - Hybrid organic–inorganic semiconductors present new opportunities for optoelectronic materials design not available in all-organic or all-inorganic materials. One example is silver phenylselenide (AgSePh) – or “mithrene” – a blue-emitting 2D organic–inorganic semiconductor exhibiting strong optical and electronic anisotropy. Here, we show that the bandgap of mithrene can be systematically tuned by introducing electron-donating and electron-withdrawing groups to the phenyl ligands. We synthesized nine mithrene variants, eight of which formed 2D van der Waals crystals analogous to those of AgSePh. Density functional theory calculations reveal that these 2D mithrene variants are direct-gap or nearly direct gap semiconductors. Furthermore, we identify correlations between the optical gap and three experimental observables – the Hammett constant,77Se chemical shift, and selenium partial charge – offering predictive power for bandgap tuning. These findings highlight new opportunities for applying the tools of chemical synthesis to semiconductor materials design.

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Systematic Bandgap Engineering of a 2D Organic–Inorganic Chalcogenide Semiconductor via Ligand Modification

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