Issue 32, 2020

Treatment-dependent surface chemistry and gas sensing behavior of the thinnest member of titanium carbide MXenes

Abstract

MXenes, a rapidly developing family of two-dimensional materials possessing tunable electronic properties and abundant surface functional groups, are promising gas-sensing materials. Ti2CTx, with a thinner unit cell thickness compared to its compositional analogue Ti3C2Tx and thus more profound surface-dependent properties, has been less explored over the past years. Herein, by etching the precursor Ti2AlC with a concentrated HF or LiF/HCl mixture, semiconducting Ti2CTx (HF) nanosheets and metallic Ti2CTx (LiF/HCl) nanosheets were obtained, respectively, arising from their treatment-dependent surface functionalization. In addition, the resulting metallic nanosheets were partially oxidized into TiO2/Ti2CTx (LiF/HCl) hybrid, which exhibited superior sensitivity toward NH3 gas as compared with Ti2CTx (HF) and Ti2CTx (LiF/HCl). Detailed analysis suggests that a high concentration of surface oxygen containing species, such as –Ox, –(OH)x and Ti–O–Ti, is generally beneficial for NH3 sensing, and a relatively higher –Ox concentration allows rapid gas desorption and sensor recovery.

Graphical abstract: Treatment-dependent surface chemistry and gas sensing behavior of the thinnest member of titanium carbide MXenes

Supplementary files

Article information

Article type
Paper
Submitted
28 Sep 2019
Accepted
09 Jul 2020
First published
17 Jul 2020

Nanoscale, 2020,12, 16987-16994

Treatment-dependent surface chemistry and gas sensing behavior of the thinnest member of titanium carbide MXenes

Q. Sun, J. Wang, X. Wang, J. Dai, X. Wang, H. Fan, Z. Wang, H. Li, X. Huang and W. Huang, Nanoscale, 2020, 12, 16987 DOI: 10.1039/C9NR08350B

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