학술논문

Detailed Analysis of the Synthesis and Structure of MAX Phase (Mo0.75V0.25)5AlC4and Its MXene Sibling (Mo0.75V0.25)5C4
Document Type
Article
Source
ACS Nano; July 2023, Vol. 17 Issue: 13 p12693-12705, 13p
Subject
Language
ISSN
19360851; 1936086X
Abstract
MAX phases with the general formula Mn+1AXnare layered carbides, nitrides, and carbonitrides with varying stacking sequence of layers of M6Xoctahedra and the Aelement depending on n. While “211” MAXphases (n= 1) are very common, MAX phases with higher n, especially n≥ 3, have hardly been prepared. This work addresses open questions regarding the synthesis conditions, structure, and chemical composition of the “514” MAX phase. In contrast to literature reports, no oxide is needed to form the MAX phase, yet multiple heating steps at 1,600 °C are required. Using high-resolution X-ray diffraction, the structure of (Mo1-xVx)5AlC4is thoroughly investigated, and Rietveld refinement suggests P-6c2 as the most fitting space group. SEM/EDS and XPS show that the chemical composition of the MAX phase is (Mo0.75V0.25)5AlC4. It was also exfoliated into its MXene sibling (Mo0.75V0.25)5C4using two different techniques (using HF and an HF/HCl mixture) that lead to different surface terminations as shown by XPS/HAXPES measurements. Initial investigations of the electrocatalytic properties of both MXene versions show that, depending on the etchant, (Mo0.75V0.25)5C4can reduce hydrogen at 10 mA cm–2with an overpotential of 166 mV (HF only) or 425 mV (HF/HCl) after cycling the samples, which makes them a potential candidate as an HER catalyst.