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Main Authors: Parekh, Urvi, Didukh, Nadiia, Dabelstein, Samira, Piehler, Ronja, Klein, Eugen, Kaushal, Jivesh, Korn, Tobias, Lochbrunner, Stefan, Klinke, Christian, Scheel, Stefan, Lesyuk, Rostyslav
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.22086
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author Parekh, Urvi
Didukh, Nadiia
Dabelstein, Samira
Piehler, Ronja
Klein, Eugen
Kaushal, Jivesh
Korn, Tobias
Lochbrunner, Stefan
Klinke, Christian
Scheel, Stefan
Lesyuk, Rostyslav
author_facet Parekh, Urvi
Didukh, Nadiia
Dabelstein, Samira
Piehler, Ronja
Klein, Eugen
Kaushal, Jivesh
Korn, Tobias
Lochbrunner, Stefan
Klinke, Christian
Scheel, Stefan
Lesyuk, Rostyslav
contents Copper selenide is an exceptional quasi-layered monolithic material that exhibits both semiconducting and metallic properties in adjacent visible and near-infrared (NIR) spectral ranges. Here we introduce a thiol-free colloidal synthesis for generating quasi-2D klockmannite copper selenide nanocrystals via hot injection method, achieving shape control by tuning the injection temperature and precursor concentrations without any additional ligands. This approach produces large klockmannite nanosheets with lateral sizes from 200 nm to several micrometres, as well as uniform triangular nanoplatelets with sizes of 12-25 nm that are monocrystalline and display strong NIR plasmonic absorption. The spectral features of the anisotropic klockmannite phase in the NIR have been analysed using complex-scaled discrete dipole approximation (CSDDA) calculations, which reveal pronounced optical anisotropy and the emergence of hyperbolic regime. The combined effect of propagating and evanescent fields is regarded as the underlying reason of such modes in the hyperbolic domain. Finally, the ultrafast photophysical behaviour of the material in klockmannite phase is examined, including hot-hole cooling, trapping, and coherent phonons generation. Our findings emphasize the important role of the intrinsic crystal anisotropy in governing the physical properties of nanoscale klockmannite.
format Preprint
id arxiv_https___arxiv_org_abs_2512_22086
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Unlocking klockmannite: formation of colloidal quasi-2D CuSe nanocrystals and photo-physical properties arising from crystal anisotropy
Parekh, Urvi
Didukh, Nadiia
Dabelstein, Samira
Piehler, Ronja
Klein, Eugen
Kaushal, Jivesh
Korn, Tobias
Lochbrunner, Stefan
Klinke, Christian
Scheel, Stefan
Lesyuk, Rostyslav
Materials Science
Copper selenide is an exceptional quasi-layered monolithic material that exhibits both semiconducting and metallic properties in adjacent visible and near-infrared (NIR) spectral ranges. Here we introduce a thiol-free colloidal synthesis for generating quasi-2D klockmannite copper selenide nanocrystals via hot injection method, achieving shape control by tuning the injection temperature and precursor concentrations without any additional ligands. This approach produces large klockmannite nanosheets with lateral sizes from 200 nm to several micrometres, as well as uniform triangular nanoplatelets with sizes of 12-25 nm that are monocrystalline and display strong NIR plasmonic absorption. The spectral features of the anisotropic klockmannite phase in the NIR have been analysed using complex-scaled discrete dipole approximation (CSDDA) calculations, which reveal pronounced optical anisotropy and the emergence of hyperbolic regime. The combined effect of propagating and evanescent fields is regarded as the underlying reason of such modes in the hyperbolic domain. Finally, the ultrafast photophysical behaviour of the material in klockmannite phase is examined, including hot-hole cooling, trapping, and coherent phonons generation. Our findings emphasize the important role of the intrinsic crystal anisotropy in governing the physical properties of nanoscale klockmannite.
title Unlocking klockmannite: formation of colloidal quasi-2D CuSe nanocrystals and photo-physical properties arising from crystal anisotropy
topic Materials Science
url https://arxiv.org/abs/2512.22086