Gas-phase synthesis of carbon nanotube-graphene heterostructures

TL;DR

This paper presents a novel gas-phase, substrate-free method for synthesizing carbon nanotube-graphene heterostructures using FCCVD, enabling controlled, versatile, and ambient-temperature production of these nanomaterials.

Contribution

It introduces a single-step FCCVD technique for direct growth of CNT-graphene heterostructures with tunable properties and broad applicability across different catalyst systems.

Findings

Successful synthesis of CNT-G heterostructures confirmed by microscopy and diffraction.

Ability to tune graphene nanoflake density by adjusting synthesis parameters.

Universal process applicable with various catalysts and setups.

Abstract

Graphene and carbon nanotubes (CNTs) share the same atomic structure of hexagonal carbon lattice. Yet, their synthesis differs in many aspects, including the shape and size of the catalyst. Here, we demonstrate a floating-catalyst chemical vapor deposition (FCCVD) technique for substrate-free, single-step growth of CNT-graphene heterostructures (CNT-G-H) using ethylene as a carbon source. The formation of CNT-G-H is directly evidenced by lattice-resolved (scanning) transmission electron microscopy (STEM) and electron diffraction experiments, corroborated by atomic force microscopy (AFM). Our experiments show the relative number density of graphene-nanoflakes can be tuned by optimizing the synthesis conditions. Since in the applied process the formation of the structures take place in gas-suspension, the as-synthesized CNT-G-H films can be deposited on any surface in ambient temperature with an arbitrary thickness. Moreover, this process of CNT-G-H synthesis with strong universality has also been realized in multiple systems of ethylene-based FCCVD with various catalysts and set-ups.