Ultra-clean isotope engineered double-walled carbon nanotubes as tailored hosts to trace the growth of carbyne

TL;DR

This study uses isotope-engineered ultra-clean double-walled carbon nanotubes to identify precursors and elucidate the growth mechanism of confined carbyne, advancing understanding of its synthesis and potential applications.

Contribution

It introduces a rational design of isotope-engineered DWCNTs as hosts to trace carbyne growth and identify its precursors, revealing the formation mechanism during high-temperature annealing.

Findings

Only inner tube carbonaceous materials act as precursors.

Exchange of C atoms occurs without carbyne growth.

Record 28.8% 13C-enriched carbyne is produced.

Abstract

Increasing attention is currently given to carbyne, the sp1 hybridized one-dimensional carbon allotrope, because of its predicted outstanding mechanical, optical, and electrical properties. Although recently substantial progress has been reported on confined carbyne synthesized inside double-walled carbon nanotubes (DWCNTs), its formation mechanism and precursors for growth remain elusive. Here, we show a rational design of isotope engineered ultra-clean DWCNTs as tailored hosts to trace the growth of carbyne, which allows to identify the precursor and unravel the formation mechanism of carbyne during high-vacuum annealing at high-temperatures. Using this approach, ultra-clean DWCNTs with 80.4% 13C-enriched inner walls and outer tubes of naturally abundant served to unambiguously prove that only the carbonaceous materials inside the DWCNTs can act as precursors. The exchange of C atoms between inner and outer tubes happens without any growth of carbyne. After applying a secondary oxidation step, it is possible to produce the carbonaceous precursors from the partially oxidized DWCNTs. In this manner, not only carbyne with a record of ~28.8% 13C enrichment is grown, but concomitant healing, reorganization and regrowth of the DWCNTs occurs. This work enables to identify the precursor and trace the growth mechanism of confined carbyne with engineered properties. This is a crucial step, towards accessing the full application potential of confined carbyne hybrids by tailoring not only the isotopic fillers, but also the inner and outer tubes of the DWCNT hosts.