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用于有毒气体传感应用的砷掺杂四方氮化硼纳米片的第一性原理研究。

First-principles investigations of As-doped tetragonal boron nitride nanosheets for toxic gas sensing applications.

作者信息

Hossain Kamal, Ahmed Mohammad Tanvir, Rabu Rabeya Akter, Ahmed Farid

机构信息

Department of Physics, Khulna University of Engineering & Technology Khulna 9203 Bangladesh.

Department of Physics, Jashore University of Science and Technology Jashore 7408 Bangladesh

出版信息

Nanoscale Adv. 2024 Nov 21;7(1):354-369. doi: 10.1039/d4na00739e. eCollection 2024 Dec 17.

DOI:10.1039/d4na00739e
PMID:39629350
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11610605/
Abstract

Pristine and arsenic-doped tetragonal boron nitride nanosheets (BNNS and As-BNNS) have been reported as potential candidates for toxic gas sensing applications. We have investigated the adsorption behavior of BNNS and As-BNNS for CO, HS, and SO gas molecules using first-principles density functional theory (DFT). Both BNNS and As-BNNS possess negative cohesive energies of -8.47 and -8.22 eV, respectively, which indicates that both sheets are energetically stable. Successful adsorption is inferred from the negative adsorption energy and structural deformation in the vicinity of the adsorbent and adsorbate. As-doping results in a significant increase in adsorption energies from -0.094, -0.175, and -0.462 eV to -2.748, -2.637, and 3.057 eV for CO, HS and SO gases, respectively. Due to gas adsorption, the electronic bandgap in As-BNNS varies by approximately 32% compared to a maximum of 24% in BNNS. A notable fluctuation in the energy gap and electrical conductivity is seen, with ambient temperature being the point of maximal sensitivity. For SO, the maximum charge transfer during adsorption in BNNS and As-BNNS is determined to be 0.08|| and 0.25||, respectively. Due to the interaction with gases, all structures exhibit an extremely high absorption coefficient on the order of 10 cm with minimal peak shifting. Additionally, doping an As atom on BNNS' surface remarkably improved its ability to sense CO, HS, and SO gasses.

摘要

据报道,纯净的和掺砷的四方氮化硼纳米片(BNNS和As-BNNS)是有毒气体传感应用的潜在候选材料。我们使用第一性原理密度泛函理论(DFT)研究了BNNS和As-BNNS对CO、HS和SO气体分子的吸附行为。BNNS和As-BNNS的内聚能分别为-8.47和-8.22 eV,均为负值,这表明这两种纳米片在能量上都是稳定的。从吸附剂和被吸附物附近的负吸附能和结构变形可以推断出成功的吸附。对于CO、HS和SO气体,掺砷使吸附能分别从-0.094、-0.175和-0.462 eV显著增加到-2.748、-2.637和-3.057 eV。由于气体吸附,As-BNNS中的电子带隙变化约32%,而BNNS中最大变化为24%。可以看到能隙和电导率有明显波动,环境温度是灵敏度最高的点。对于SO,在BNNS和As-BNNS中吸附过程中的最大电荷转移分别确定为0.08||和0.25||。由于与气体的相互作用,所有结构都表现出极高的吸收系数,约为10 cm,且峰位移动最小。此外,在BNNS表面掺杂一个As原子显著提高了其对CO、HS和SO气体的传感能力。

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