First-principles explorations on 2D transition metal diborides featuring inverse sandwich structures and their gas sensing properties

Journal of Physics D: Applied Physics Pub Date : 2024-07-15 DOI:10.1088/1361-6463/ad6331

Shukai Wang, Kai Shi, Jie Li, Juan Lyu, Fengyu Li

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Abstract

First-principles calculations were carried out to investigate the stability of two dimensional (2D) MB2 monolayers (TiB2-I, VB2-I, MnB2-I, TiB2-II, ScB2-II, NiB2-II) with an inverse sandwich configuration and their potential as efficient gas sensors to detect toxic gas molecules. We first identified five stable 2D MB2 configurations, based on stability evaluation covering thermodynamical, dynamical, and thermal aspects. To investigate the performance of these novel structures as gas sensors, the adsorption behavior of five toxic gas molecules (CO, NO, NO2, NH3, SO2) on MB2 has been explored, and the charge transfer and magnetic changes of these adsorption systems were analyzed. It is found that five gases are all chemisorbed on 2D MB2. Particularly, when CO is adsorbed on TiB2-II, the magnetism of the system undergoes a significant change from non-magnetism to antiferromagnetism, showing selectivity for CO. Furthermore, the current−voltage characteristics obtained from simulations confirm gas sensing performance. The TiB2-II is expected to be a candidate material for CO gas sensor with short recovery time (7.50 ×10−10 s). Our theoretical study provides new ideas for designing gas sensor nanomaterials with magnetism alteration as the indicator featuring easy measurement and fast response.

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具有反三明治结构的二维过渡金属二硼化物及其气体传感特性的第一性原理探索

我们进行了第一性原理计算，以研究具有反三明治构型的二维（2D）MB2 单层（TiB2-I、VB2-I、MnB2-I、TiB2-II、ScB2-II、NiB2-II）的稳定性及其作为高效气体传感器检测有毒气体分子的潜力。根据热力学、动力学和热学方面的稳定性评估，我们首先确定了五种稳定的二维 MB2 构型。为了研究这些新型结构作为气体传感器的性能，我们探索了五种有毒气体分子（CO、NO、NO2、NH3、SO2）在 MB2 上的吸附行为，并分析了这些吸附体系的电荷转移和磁性变化。研究发现，五种气体都能在二维 MB2 上发生化学吸附。特别是当一氧化碳吸附在 TiB2-II 上时，体系的磁性发生了显著变化，从非磁性变为反铁磁性，显示出对一氧化碳的选择性。此外，模拟得到的电流-电压特性也证实了气体传感性能。预计 TiB2-II 将成为一氧化碳气体传感器的候选材料，其恢复时间短（7.50 ×10-10 秒）。我们的理论研究为设计以磁性变化为指标的气体传感器纳米材料提供了新思路，这种材料具有测量简便、响应快速的特点。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Physics D: Applied Physics

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