Efficient Defect-Driven Cation Exchange beyond the Nanoscale Semiconductors toward Antibacterial Functionalization

Svetlana Polivtseva; Olga Volobujeva; Ivan Kuznietsov; Reelika Kaupmees; Mati Danilson; Jüri Krustok; Palanivel Molaiyan; Tao Hu; Ulla Lassi; Mihhail Klopov; Heleen van Gog; Marijn A. van Huis; Harleen Kaur; Angela Ivask; Merilin Rosenberg; Nicholas Gathergood; Chaoying Ni; Maarja Grossberg-Kuusk

doi:10.1021/acsami.4c11425

Efficient Defect-Driven Cation Exchange beyond the Nanoscale Semiconductors toward Antibacterial Functionalization

Svetlana Polivtseva^*, Olga Volobujeva, Ivan Kuznietsov, Reelika Kaupmees, Mati Danilson, Jüri Krustok, Palanivel Molaiyan, Tao Hu, Ulla Lassi, Mihhail Klopov, Heleen van Gog, Marijn A. van Huis, Harleen Kaur, Angela Ivask, Merilin Rosenberg, Nicholas Gathergood, Chaoying Ni, Maarja Grossberg-Kuusk

^*Corresponding author for this work

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

Abstract

Defect engineering is an exciting tool for customizing semiconductors’ structural and optoelectronic properties. Elaborating programmable methodologies to circumvent energy constraints in multievent inversions expands our understanding of the mechanisms governing the functionalization of nanomaterials. Herein, we introduce a novel strategy based on defect incorporation and solution rationalization, which triggers energetically unfavorable cation exchange reactions in extended solids. Using Sb₂X₃ + Ag (I) → Ag: Sb₂X₃ (X= S, Se) as a system to model, we demonstrate that incorporating chalcogen vacancies and Ag_SbV_X complex defects into initial thin films (TFs) is crucial for activating long-range solid-state ion diffusion. Additional regulation of the Lewis acidity of auxiliary chemicals provides an exceptional conversion yield of the Ag precursor into a solid-state product up to 90%, simultaneously transforming upper matrix layers into AgSbX₂. The proposed strategy enables tailoring radiative recombination processes, offers efficiency to invert TFs at moderate temperatures quickly, and yields structures of large areas with substantial antibacterial activity in visible light for a particular inversion system. Similar customization can be applied to most sulfides/selenides with controlled reaction yields.

Original language	English
Pages (from-to)	62871-62882
Number of pages	12
Journal	ACS Applied Materials and Interfaces
Volume	16
Issue number	45
Early online date	30 Oct 2024
DOIs	https://doi.org/10.1021/acsami.4c11425
Publication status	Published - 13 Nov 2024

Bibliographical note

Publisher Copyright:
© 2024 The Authors. Published by American Chemical Society.

Funding

We acknowledge support from the Estonian Research Council under grant no. MOBTP1005, no. PSG813, no. PRG1023, no. PRG1496, no. TEM-TA55 and the Center of Excellence project no. TK210. This research used facilities in the University of Oulu supported by Business Finland under the grant BATCircle2.0 and Dnro 44612/31/2020. U.L. was supported by the Finnish Research Impact Foundation for Tandem Industry Academia professorship for 2023-2025.

Funders	Funder number
Eesti Teadusagentuur	MOBTP1005, PSG813, PRG1023, PRG1496, TEM-TA55, TK210
Estonian Research Council	BATCircle2.0, Dnro 44612/31/2020
Business Finland	2023-2025
Finnish Research Impact Foundation for Tandem Industry Academia professorship

Keywords

antibacterial materials
defect chemistry
DFT calculation
doping V−VI metal chalcogenides
ion exchange
materials design
photoluminescence
thin films

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10.1021/acsami.4c11425Licence: CC BY

polivtseva-et-al-2024-efficient-defect-driven-cation-exchange-beyond-the-nanoscale-semiconductors-toward-antibacterialFinal published version, 5.15 MBLicence: CC BY

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Polivtseva, S., Volobujeva, O., Kuznietsov, I., Kaupmees, R., Danilson, M., Krustok, J., Molaiyan, P., Hu, T., Lassi, U., Klopov, M., van Gog, H., van Huis, M. A., Kaur, H., Ivask, A., Rosenberg, M., Gathergood, N., Ni, C., & Grossberg-Kuusk, M. (2024). Efficient Defect-Driven Cation Exchange beyond the Nanoscale Semiconductors toward Antibacterial Functionalization. ACS Applied Materials and Interfaces, 16(45), 62871-62882. https://doi.org/10.1021/acsami.4c11425

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abstract = "Defect engineering is an exciting tool for customizing semiconductors{\textquoteright} structural and optoelectronic properties. Elaborating programmable methodologies to circumvent energy constraints in multievent inversions expands our understanding of the mechanisms governing the functionalization of nanomaterials. Herein, we introduce a novel strategy based on defect incorporation and solution rationalization, which triggers energetically unfavorable cation exchange reactions in extended solids. Using Sb2X3 + Ag (I) → Ag: Sb2X3 (X= S, Se) as a system to model, we demonstrate that incorporating chalcogen vacancies and AgSbVX complex defects into initial thin films (TFs) is crucial for activating long-range solid-state ion diffusion. Additional regulation of the Lewis acidity of auxiliary chemicals provides an exceptional conversion yield of the Ag precursor into a solid-state product up to 90%, simultaneously transforming upper matrix layers into AgSbX2. The proposed strategy enables tailoring radiative recombination processes, offers efficiency to invert TFs at moderate temperatures quickly, and yields structures of large areas with substantial antibacterial activity in visible light for a particular inversion system. Similar customization can be applied to most sulfides/selenides with controlled reaction yields.",

keywords = "antibacterial materials, defect chemistry, DFT calculation, doping V−VI metal chalcogenides, ion exchange, materials design, photoluminescence, thin films",

author = "Svetlana Polivtseva and Olga Volobujeva and Ivan Kuznietsov and Reelika Kaupmees and Mati Danilson and J{\"u}ri Krustok and Palanivel Molaiyan and Tao Hu and Ulla Lassi and Mihhail Klopov and {van Gog}, Heleen and {van Huis}, {Marijn A.} and Harleen Kaur and Angela Ivask and Merilin Rosenberg and Nicholas Gathergood and Chaoying Ni and Maarja Grossberg-Kuusk",

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month = nov,

day = "13",

doi = "10.1021/acsami.4c11425",

language = "English",

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Polivtseva, S, Volobujeva, O, Kuznietsov, I, Kaupmees, R, Danilson, M, Krustok, J, Molaiyan, P, Hu, T, Lassi, U, Klopov, M, van Gog, H, van Huis, MA, Kaur, H, Ivask, A, Rosenberg, M, Gathergood, N, Ni, C & Grossberg-Kuusk, M 2024, 'Efficient Defect-Driven Cation Exchange beyond the Nanoscale Semiconductors toward Antibacterial Functionalization', ACS Applied Materials and Interfaces, vol. 16, no. 45, pp. 62871-62882. https://doi.org/10.1021/acsami.4c11425

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AU - Polivtseva, Svetlana

AU - Volobujeva, Olga

AU - Kuznietsov, Ivan

AU - Kaupmees, Reelika

AU - Danilson, Mati

AU - Krustok, Jüri

AU - Molaiyan, Palanivel

AU - Hu, Tao

AU - Lassi, Ulla

AU - Klopov, Mihhail

AU - van Gog, Heleen

AU - van Huis, Marijn A.

AU - Kaur, Harleen

AU - Ivask, Angela

AU - Rosenberg, Merilin

AU - Gathergood, Nicholas

AU - Ni, Chaoying

AU - Grossberg-Kuusk, Maarja

PY - 2024/11/13

Y1 - 2024/11/13

N2 - Defect engineering is an exciting tool for customizing semiconductors’ structural and optoelectronic properties. Elaborating programmable methodologies to circumvent energy constraints in multievent inversions expands our understanding of the mechanisms governing the functionalization of nanomaterials. Herein, we introduce a novel strategy based on defect incorporation and solution rationalization, which triggers energetically unfavorable cation exchange reactions in extended solids. Using Sb2X3 + Ag (I) → Ag: Sb2X3 (X= S, Se) as a system to model, we demonstrate that incorporating chalcogen vacancies and AgSbVX complex defects into initial thin films (TFs) is crucial for activating long-range solid-state ion diffusion. Additional regulation of the Lewis acidity of auxiliary chemicals provides an exceptional conversion yield of the Ag precursor into a solid-state product up to 90%, simultaneously transforming upper matrix layers into AgSbX2. The proposed strategy enables tailoring radiative recombination processes, offers efficiency to invert TFs at moderate temperatures quickly, and yields structures of large areas with substantial antibacterial activity in visible light for a particular inversion system. Similar customization can be applied to most sulfides/selenides with controlled reaction yields.

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KW - antibacterial materials

KW - defect chemistry

KW - DFT calculation

KW - doping V−VI metal chalcogenides

KW - ion exchange

KW - materials design

KW - photoluminescence

KW - thin films

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AN - SCOPUS:85208048542

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JF - ACS Applied Materials and Interfaces

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ER -

Efficient Defect-Driven Cation Exchange beyond the Nanoscale Semiconductors toward Antibacterial Functionalization

Abstract

Bibliographical note

Funding

Keywords

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