Nanotube-based one-dimensional heterostructures coupled by van der Waals forces

TL;DR

This review explores the synthesis, properties, and potential applications of one-dimensional van der Waals heterostructures based on carbon nanotubes, emphasizing their unique tunable features compared to 2D counterparts.

Contribution

It provides a comprehensive overview of current methods, properties, and design parameters for 1D heterostructures, highlighting their potential for custom optical and electronic applications.

Findings

Van der Waals coupling significantly influences nanotube heterostructure properties.

Diameter and chiral structure offer additional design parameters.

Potential for integrating heterostructures into diverse applications.

Abstract

One-dimensional (1D) van der Waals heterostructures based on carbon nanotube templates are raising a lot of excitement due to the possibility of creating new optical and electronic properties, by either confining molecules inside their hollow core or by adding layers on the outside of the nanotube. In contrast to their 2D analogues, where the number of layers, atomic type and relative orientation of the constituting layers are the main parameters defining physical properties, 1D heterostructures provide an additional degree of freedom, i.e. their specific diameter and chiral structure, for engineering their characteristics. This review discusses the current state-of-the-art in synthesizing 1D heterostructures, in particular focusing on their resulting optical properties, and details the vast parameter space that can be used to design heterostructures with custom-built properties that can be integrated into a large variety of applications. The review starts from describing the effects of van der Waals coupling on the properties of the simplest and best-studied 1D heterostructure, namely a double-wall carbon nanotube, then considers heterostructures built from the inside and the outside, which all use a nanotube as a template, and, finally, provides an outlook for the future of this research field.