钯簇修饰石墨烯的可调甲醛传感特性

Tunable formaldehyde sensing properties of palladium cluster decorated graphene.

作者信息

Yang Lunwei, Xiao Wei, Wang Jianwei, Li Xiaowu, Wang Ligen

机构信息

State Key Laboratory of Nonferrous Metals and Processes, GRINM Group Co., Ltd. Beijing 100088 P. R. China

GRIMAT Engineering Institute Co., Ltd. Beijing 101407 P. R. China.

出版信息

RSC Adv. 2021 Nov 18;11(59):37120-37130. doi: 10.1039/d1ra06940c. eCollection 2021 Nov 17.

DOI:10.1039/d1ra06940c

PMID:35496415

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9043533/

Abstract

The ability to tune the adsorption strength of the targeted gas on sensing materials is crucial for sensing applications. By employing first-principles calculations the adsorption and sensing properties of HCHO on small Pd ( = 1-6) cluster decorated graphene have been systematically investigated. The adsorption energy is found to depend on the size of the Pd cluster and can be tuned in a wide range from -0.68 eV on Pd(111) to -1.98 eV on the Pd/graphene system. We also find that the Pd /graphene ( = 5 and 6) systems have an appropriate adsorption energy for HCHO gas sensing. The current-voltage curves are calculated by the non-equilibrium Green's function method for the two-probe nano-sensor devices along both the armchair and zigzag directions. The devices constructed with Pd /graphene ( = 5 and 6), having the highest absolute response over 20% at small voltages, should be applicable for HCHO detection. This work provides a theoretical basis for exploring potential applications of metal cluster decorated graphene for gas sensing.

摘要

调节目标气体在传感材料上的吸附强度的能力对于传感应用至关重要。通过采用第一性原理计算，系统地研究了HCHO在小尺寸Pd（n = 1 - 6）团簇修饰的石墨烯上的吸附和传感特性。发现吸附能取决于Pd团簇的尺寸，并且可以在从Pd(111)上的-0.68 eV到Pd/石墨烯体系上的-1.98 eV的宽范围内进行调节。我们还发现Pd₅/石墨烯和Pd₆/石墨烯体系对于HCHO气体传感具有合适的吸附能。通过非平衡格林函数方法计算了沿扶手椅和锯齿方向的两探针纳米传感器器件的电流 - 电压曲线。由Pd₅/石墨烯和Pd₆/石墨烯构建的器件在小电压下具有超过20%的最高绝对响应，应适用于HCHO检测。这项工作为探索金属团簇修饰的石墨烯在气体传感方面的潜在应用提供了理论基础。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cd54/9043533/275a58378197/d1ra06940c-f1.jpg

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钯簇修饰石墨烯的可调甲醛传感特性

Tunable formaldehyde sensing properties of palladium cluster decorated graphene.

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