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Main Authors: Sakurada, Tomoaki, Lee, Woo Seok, Cho, Yeongsu, Khamlue, Rattapon, Chatsiri, Petcharaphorn, Samulewicz, Nicholas, Deshpande, Tejas, Su, Annlin, Müller, Peter, Kawamoto, Tadashi, Omagari, Shun, Vacha, Martin, Paritmongkol, Watcharaphol, Kulik, Heather J., Tisdale, William A.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.23138
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author Sakurada, Tomoaki
Lee, Woo Seok
Cho, Yeongsu
Khamlue, Rattapon
Chatsiri, Petcharaphorn
Samulewicz, Nicholas
Deshpande, Tejas
Su, Annlin
Müller, Peter
Kawamoto, Tadashi
Omagari, Shun
Vacha, Martin
Paritmongkol, Watcharaphol
Kulik, Heather J.
Tisdale, William A.
author_facet Sakurada, Tomoaki
Lee, Woo Seok
Cho, Yeongsu
Khamlue, Rattapon
Chatsiri, Petcharaphorn
Samulewicz, Nicholas
Deshpande, Tejas
Su, Annlin
Müller, Peter
Kawamoto, Tadashi
Omagari, Shun
Vacha, Martin
Paritmongkol, Watcharaphol
Kulik, Heather J.
Tisdale, William A.
contents 2D materials exhibiting in-plane anisotropy enable novel functionality in electronic, optoelectronic, and photonic devices, yet their availability is generally limited to naturally-occurring low-symmetry van der Waals compounds. Here, we demonstrate an approach to structural engineering in a family of blue-emitting 2D silver phenylchalcogenide semiconductors based on steric interactions among surface-bound organic molecular ligands. By strategically halogenating specific sites of phenyl ligands, we demonstrate dramatic changes to the inorganic AgSe plane in mithrene (silver phenylselenolate, AgSePh). Density functional theory revealed pronounced in-plane electronic anisotropy for direct-gap fluorinated derivatives, while a chlorinated variant exhibited a direct-to-indirect bandgap transition. Furthermore, some fluorinated variants displayed strongly polarized absorption and luminescence, accompanied by a 10x enhancement in photoluminescence quantum yield. This work establishes a versatile approach for tailoring optoelectronic properties in hybrid semiconductors that is difficult or impossible to achieve in all-inorganic materials alone, offering new opportunities in advanced material design.
format Preprint
id arxiv_https___arxiv_org_abs_2602_23138
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Engineering in-plane anisotropy in 2D materials via surface-bound ligands
Sakurada, Tomoaki
Lee, Woo Seok
Cho, Yeongsu
Khamlue, Rattapon
Chatsiri, Petcharaphorn
Samulewicz, Nicholas
Deshpande, Tejas
Su, Annlin
Müller, Peter
Kawamoto, Tadashi
Omagari, Shun
Vacha, Martin
Paritmongkol, Watcharaphol
Kulik, Heather J.
Tisdale, William A.
Materials Science
Mesoscale and Nanoscale Physics
2D materials exhibiting in-plane anisotropy enable novel functionality in electronic, optoelectronic, and photonic devices, yet their availability is generally limited to naturally-occurring low-symmetry van der Waals compounds. Here, we demonstrate an approach to structural engineering in a family of blue-emitting 2D silver phenylchalcogenide semiconductors based on steric interactions among surface-bound organic molecular ligands. By strategically halogenating specific sites of phenyl ligands, we demonstrate dramatic changes to the inorganic AgSe plane in mithrene (silver phenylselenolate, AgSePh). Density functional theory revealed pronounced in-plane electronic anisotropy for direct-gap fluorinated derivatives, while a chlorinated variant exhibited a direct-to-indirect bandgap transition. Furthermore, some fluorinated variants displayed strongly polarized absorption and luminescence, accompanied by a 10x enhancement in photoluminescence quantum yield. This work establishes a versatile approach for tailoring optoelectronic properties in hybrid semiconductors that is difficult or impossible to achieve in all-inorganic materials alone, offering new opportunities in advanced material design.
title Engineering in-plane anisotropy in 2D materials via surface-bound ligands
topic Materials Science
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2602.23138