Microflowers Composed of VO<sub>2</sub> Nanoflakes for Selective Detection of Acetone and Ammonia
Yuxiang Qin, Haoxuan Wang, Chuan Zhou, Yinan Bai
Abstract
As a typical phase-transition material, VO 2 could show great potential in the process of precise modulation of gas-sensing selectivity. However, the effect and mechanism of the phase transition on its gas sensitivity have not yet been clearly elucidated. In this paper, a temperature-controlled VO 2 gas sensor capable of phase change has been created using a one-step solvothermal method. With controllable transition of VO 2 from the monoclinic phase to the rutile phase by adjusting the operating temperature, the corresponding VO 2 sensor shows obvious changes in gas-sensing selectivity from acetone to ammonia. At room temperature (∼25 °C), the monoclinic VO 2 sensor produces response values of 93 and 29% to 10 ppm of acetone vapor and ammonia gas, respectively. Comparatively, the response values for the sensor based on rutile-phase VO 2 that operates at 100 °C are 41 and 95% for 10 ppm of acetone vapor and ammonia gas. Based on the first-principles mortise–tenon-style construction as well as Lewis acid–base theory, the mechanism of dual selectivity generated with the phase transition of VO 2 is demonstrated in terms of crystal structure, electronic orbitals, and adsorption energy calculations. The unique characteristic of adjustable dual-phase detectability of VO 2 contributes to the selective capability of gas sensing. It thus presents an effective strategy for developing gas sensors with regulated selectivity by phase transition of certain special semiconductor oxides.