Application of Micro-mass Monitoring in Corrosion of Nanomaterials and its Innovation

Xianjun Rong; Changkun Zhu

doi:10.6919/ICJE.202501_11(1).0010

Authors

Xianjun Rong
Changkun Zhu

DOI:

https://doi.org/10.6919/ICJE.202501_11(1).0010

Keywords:

Mass Method; Corrosion; Copper Nanowires; Activation Energy.

Abstract

In this paper, based on the microscopic mass change monitoring technology, the microscopic mass method was used for the first time to detect the mass change of adsorbed nitrogen dioxide by nanowire materials in real time and to calculate the kinetics of the reaction process of adsorption of acidic gases by its nanomaterials by combining with the Arrhenius equation and adsorption isotherm theory. We conclude that the activation energy of its corrosion process is 75kJ/mol, and we find that it is irrecoverable after adsorption of nitrogen dioxide through multi-concentration real-time monitoring, and the corrosion rate of copper nanowires in nitrogen dioxide is extremely fast, and the corrosion resistance is still a big challenge.

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