Issue 20, 2023

Making coordination networks ionic: a unique strategy to achieve solution-processable hybrid semiconductors

Abstract

The development of high-performance, solution-processable semiconducting materials is crucial for the advancement of emerging clean-energy technologies such as light-emitting diodes and photovoltaics. While hybrid perovskites have shown considerable promise for implementation in these technologies, their reliance on toxic metals and relatively low stability towards moisture and chemical environments remain to be addressed. In this Chemistry Frontiers article, we describe a unique strategy to build nontoxic, robust and solution-processable hybrid semiconductors based on copper halide by incorporating ionic bonds in coordination complexes (molecular or extended network structures). Specifically, these compounds are made of anionic copper(I) halide and cationic organic ligands that form both coordinate and ionic bonds at the inorganic/organic interfaces and are referred to as all-in-one (AIO)-type structures. The unique bonding nature renders the AIO-type structures with greatly enhanced solubility, excellent optical tunability and remarkable framework stability, all highly desirable for thin-film based optoelectronic devices. We will highlight the most recent progress in the development of this material group, including their design strategies, important properties and potential for clean-energy related applications. We will also briefly discuss the existing challenges and future outlook of these materials.

Graphical abstract: Making coordination networks ionic: a unique strategy to achieve solution-processable hybrid semiconductors

Article information

Article type
Chemistry Frontiers
Submitted
04 Mai 2023
Accepted
06 Aug 2023
First published
08 Aug 2023

Mater. Chem. Front., 2023,7, 4598-4604

Author version available

Making coordination networks ionic: a unique strategy to achieve solution-processable hybrid semiconductors

X. Hei and J. Li, Mater. Chem. Front., 2023, 7, 4598 DOI: 10.1039/D3QM00515A

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