Colloidal two-dimensional metal chalcogenides: Realization and application of the structural anisotropy

TL;DR

This paper reviews recent advances in the synthesis, properties, and applications of colloidal two-dimensional metal chalcogenides, highlighting their potential in optoelectronics, photovoltaics, and spintronics.

Contribution

It provides a comprehensive overview of the synthesis mechanisms, structural anisotropy, and optical properties of colloidal 2D metal chalcogenides, emphasizing recent progress and future prospects.

Findings

Growth of 2D colloidal chalcogenides involves structural asymmetry or ligand assistance.

Optical spectroscopy reveals unique electronic and excitonic features.

Potential applications in photovoltaics, optoelectronics, and spintronics.

Abstract

Due to the spatial confinement, two-dimensional metal chalcogenides display an extraordinary optical re-sponse and carrier transport ability. Solution-based synthesis techniques such as colloidal hot injection and ion exchange provide a cost-effective way to fabricate such low-dimensional semiconducting nanocrystals. Over the years, developments in colloidal chemistry made it possible to synthesize various kinds of ultrathin colloidal nanoplatelets, including wurtzite- and zinc blende-type CdSe, rocksalt PbS, black phosphorus-like SnX (X=S or Se), hexagonal copper sulfides, selenides and even transition metal dichalcogenides (TMD) like MoS2. By altering experimental conditions and applying capping ligands with specific functional groups, it is possible to accurately tune the dimensionality, geometry and consequently the optical prop-erties of these colloidal metal chalcogenide crystals. Here, we review recent progresses in the syntheses of two-dimensional colloidal metal chalcogenides (CMCs) and property characterizations based on optical spectroscopy or device-related meas-urements. The discoveries shine a light on their huge prospect for applications in areas such as photovoltaics, optoelectronics and spintronics. In specific, the formation mechanisms of two-dimensional CMCs are discussed. The growth of colloidal nano-crystals into a two-dimensional shape is found to require either an intrinsic structural asymmetry or the assist of coexisted ligand molecules, which act as lamellar double-layer templates or "facet" the crystals via selective adsorption. By performing optical characterizations and especially ultrafast spectroscopic measurements on these two-dimensional CMCs, their unique electronic and excitonic features are revealed.