| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| Research Advances in Low-temperature Plasma Technology-modified Materials for Atmospheric Pollutant Treatment |
| HAN Minghong, LI Fen*, YANG Ying, YANG Dongdong, WANG Ruiying, XING Zhichao
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| The School of Material Science and Chemical Engineering, Harbin University of Science and Technology, Harbin 150000, China |
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Abstract Low-temperature plasma (LTP) material modification technology is widely utilized in materials engineering due to its significant advantages, including operational simplicity, environmental compatibility, rapid processing, and pronounced functional efficacy. This review outlines the evolution of LTP technology and elucidates the generation mechanisms and material modification functionalities of four principal discharge modes: glow discharge (GD), atmospheric pressure plasma jet (APPJ), corona discharge (CD), and dielectric barrier discharge (DBD). It focuses specifically on the research applications and removal mechanisms of LTP-modified materials in mitigating key atmospheric pollutants such as SO2, NOX, H2S, volatile organic compounds (VOCs), and mercury (Hg). Furthermore, the current research status, advantages, and limitations of LTP-modified materials for diverse air pollutant abatement are critically summarized. Analysis indicates that despite notable breakthroughs in precise surface engineering, the field must address persistent challenges including the elucidation of multi-scale reaction mechanisms, development of intelligent process control, and enhancement of scalability for engineering applications. This review aims to provide a theoretical foundation and identify potential technical pathways for advancing LTP applications in environmental functional material design and atmospheric pollution control.
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Received: 10 May 2026
Published:
Online: 2026-05-18
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2026, Vol. 40 
