H2S Gas Sensitivity of Doped SbP Monolayer：First Principle Study

IF 0.6 4区化学 Q4 CHEMISTRY, MULTIDISCIPLINARY Journal of the chemical society of pakistan Pub Date : 2023-01-01 DOI:10.52568/001242/jcsp/45.03.2023

Dong Li Dong Li, Xiaolei Li Xiaolei Li, Tengfei Wang Tengfei Wang, Lu Li and Junkai Wang Lu Li and Junkai Wang

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Abstract

The sensing behaviors of monolayer antimonide phosphorus (SbP) for hydrogen sulfide (H2S) are investigated by means of the density functional theory. In this paper, we calculated the best adsorption configuration, charge transfer, adsorption distance, band gap, electronic structure and recovery time of H2S on the SbP monolayer and mental-doped SbP (X-SbP). The calculated results indicate that Al atom replaces Sb atom of SbP (Al-Sb-SbP), adsorption capacity was greatly increased, but the covalent bond formed between the gas molecules and the substrate was not suitable for sensing materials. And though Co or Ni atom could improve the interactions between H2S gas and SbP sheets, the recovery time was too long. It was also not suitable for the sensor material of H2S gas. However, for Pd doped SbP, Pd-Sb and Pd-P doping all exhibit excellent gas sensing performance for H2S gas with the adsorption energy of -0.677eV and -0.520eV, the charge transfer 0.1113e and 0.0930e, the recovery time 0.19s and 5.30and#215;10-4 s, respectively. These characters made Pd-SbP suitable for H2S gas sensing material. Which further analysis we knew that these changes were mainly due to the orbital hybridization between the s, p orbitals of Pd atom and the p orbitals of S atom. Theoretical studies show that Pd-doped SbP is a promising H2S gas sensing material

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掺杂SbP单层H2S气敏性的第一性原理研究

利用密度泛函理论研究了单层锑化磷(SbP)对硫化氢(H2S)的传感行为。本文计算了H2S在SbP单层和掺杂SbP (X-SbP)上的最佳吸附构型、电荷转移、吸附距离、带隙、电子结构和恢复时间。计算结果表明，Al原子取代SbP中的Sb原子(Al-Sb-SbP)，吸附能力大大提高，但气体分子与底物之间形成的共价键不适合作为传感材料。虽然Co或Ni原子可以改善H2S气体与SbP片的相互作用，但恢复时间过长。它也不适合作为H2S气体的传感器材料。而对于Pd掺杂的SbP, Pd- sb和Pd- p掺杂均表现出优异的气敏性能，对H2S气体的吸附能分别为-0.677eV和-0.520eV，电荷转移量分别为0.1113e和0.0930e，恢复时间分别为0.19s和5.30 s和#215;10-4 s。这些特性使Pd-SbP适合作为H2S气敏材料。进一步的分析表明，这些变化主要是由于Pd原子的s、p轨道和s原子的p轨道之间的杂化作用。理论研究表明，掺pd的SbP是一种很有前途的H2S气敏材料

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来源期刊

Journal of the chemical society of pakistan 化学-化学综合

CiteScore

1.30

自引率

14.30%

发文量

审稿时长

3.4 months

期刊介绍： This journal covers different research areas in the field of Chemistry. These include; Analytical Chemistry, Applied Chemistry, Biochemistry, Environmental Chemistry, Industrial Chemistry, Inorganic Chemistry, Organic Chemistry and Physical Chemistry. The journal publishes full length articles and Reviews from researchers in academia in addition to featuring comments. Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry.