Title : ( Conversion of 2D MXene to Multi‐Low‐Dimensional GerMXene Superlattice Heterostructure )
Authors: Alireza Rafieerad , Ahmad Amiri , Weiang Yan , Hossein Eshghi , Sanjiv Dhingra ,Access to full-text not allowed by authors
Abstract
Integration of 2D structures into other low-dimensional materials results in the development of distinct van der Waals heterostructures (vdWHSs) with enhanced properties. However, obtaining 2D–1D–0D vdWHSs of technologically useful next generation materials, transition-metal carbide MXene and monoelemental Xene nanosheets in a single superlattice heterostructure is still challenging. Here, the fabrication of a new multidimensional superlattice heterostructure “GerMXene” from exfoliated M3X2Tx MXene and hydrogenated germanane (GeH) crystals, is reported. Direct experimental evidence for conversion of hydrothermally activated titanium carbide MXene (A-MXene) to GerMXene heterostructure through the rapid and spontaneous formation of titanium germanide (TiGe2 and Ti6Ge5) bonds, is provided. The obtained GerMXene heterostructure possesses enhanced surface properties, aqueous dispersibility, and Dirac signature of embedded GeH nanosheets as well as quantum dots. GerMXene exhibits functional bioactivity, electrical conductivity, and negative surface charge, paving ways for its applications in biomedical field, electronics, and energy storage.
Keywords
, low-dimensional materials , MXene, GerMXene, Superlattice Heterostructure@article{paperid:1087587,
author = {Alireza Rafieerad and Ahmad Amiri and Weiang Yan and Eshghi, Hossein and Sanjiv Dhingra},
title = {Conversion of 2D MXene to Multi‐Low‐Dimensional GerMXene Superlattice Heterostructure},
journal = {Advanced Functional Materials},
year = {2021},
volume = {32},
number = {10},
month = {November},
issn = {1616-301X},
keywords = {low-dimensional materials ; MXene; GerMXene; Superlattice Heterostructure},
}
%0 Journal Article
%T Conversion of 2D MXene to Multi‐Low‐Dimensional GerMXene Superlattice Heterostructure
%A Alireza Rafieerad
%A Ahmad Amiri
%A Weiang Yan
%A Eshghi, Hossein
%A Sanjiv Dhingra
%J Advanced Functional Materials
%@ 1616-301X
%D 2021