Issue 44, 2024

Superstructures of copper nanoclusters as NIR TADF emitters: solvent-dependent optical and morphological modulation

Abstract

Herein, we report 2-mercaptopyridine-templated copper nanoclusters (CuNCs) which display near infra-red (NIR) emission, both in the solid and colloidal states. Interestingly, the NIR emission can be modulated to orange emission by preparing the CuNCs in a mixed solvent system of chloroform and methanol instead of water. The drastic change in the photo-physical properties of the CuNCs when prepared in two different solvent systems is accompanied by a unique morphological tuning. Further studies reveal that the strong NIR emission is the result of thermally activated delayed fluorescence (TADF) which is confirmed by the long excited state lifetime (∼4 μs at room temperature), time resolved emission spectroscopy (TRES) measurements, temperature-dependent photoluminescence studies, temperature-dependent lifetime studies, and excitation-transmittance dependent TRES intensity measurements. The CuNCs exhibit an exceptionally small singlet–triplet energy gap of 58.2 meV, indicating a highly efficient TADF in the system. Moreover, the solvent-dependent morphological tuning of the nanocluster superstructures rendering a drastic change in the photo-physical signatures is the consequence of different ΔE(S1–T1) values for the CuNCs in different solvent environments. Further findings corroborate that the electronic structure of the surface ligands can also help us to tune the ΔE(S1–T1) energy gap for these nanoclusters.

Graphical abstract: Superstructures of copper nanoclusters as NIR TADF emitters: solvent-dependent optical and morphological modulation

Supplementary files

Article information

Article type
Paper
Submitted
25 Jul 2024
Accepted
05 Oct 2024
First published
07 Oct 2024

Nanoscale, 2024,16, 20556-20569

Superstructures of copper nanoclusters as NIR TADF emitters: solvent-dependent optical and morphological modulation

S. Agrawal, D. Shil, A. Gupta and S. Mukherjee, Nanoscale, 2024, 16, 20556 DOI: 10.1039/D4NR03074E

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