材料科学
纳米材料
纳米技术
化学气相沉积
成核
表面改性
等离子体处理
微等离子体
活性材料
等离子体
沉积(地质)
多孔性
化学工程
热喷涂
热解
热的
猝灭(荧光)
氢
化学合成
化学反应
高能材料
球形
化学过程
材料加工
金属
氧化物
大气压等离子体
作者
Liuyang Bai,Hongbing Wang,Meiping Liu,Yunting Liang,Zongxian Yang,Yuge Ouyang,Yunxiao Yang,Fangli Yuan
标识
DOI:10.1088/2058-6272/ae400a
摘要
Abstract The plasma-enhanced process, leveraging the unique properties of thermal plasma—including extreme temperatures (~ 10 4 K), high energy density, high chemical activity and rapid quenching rates—offers a distinct advantage over conventional methods for powder material synthesis and processing. This review comprehensively examines the principles and applications of thermal plasma in tailoring powder properties. Beginning with a clear technological positioning that contrasts thermal plasma with mainstream conventional powder synthesis methods, highlighting its unique role in processing extreme materials and enabling single-step synthesis through integrated physical and chemical transformations, the discussion then proceeds to a detailed examination of its various applications in materials processing. It first delves into plasma spheroidization, detailing how it transforms irregular powders into dense particles with high sphericity and superior flowability for additive manufacturing, and elaborates on the three-stage mechanism (melting, volume change and solidification) of forming hollow spherical particles from porous aggregates for functional applications. The review then explores plasma-enhanced physical vapor deposition (PEPVD), illustrating its capability for dimension-controlled nanomaterial synthesis, where precisely manipulated temperature fields and cooling rates dictate the nucleation and growth pathways, enabling the synthesis of nanomaterials with diverse and tailored architectures. A significant focus is placed on plasma-enhanced chemical synthesis (PECS), systematically presented along a progression of increasing chemical complexity. This includes efficient pyrolysis of precursor compounds to synthesize nanoparticles; hydrogen plasma reduction of metal oxides for green metallurgy; oxidation of metals to create spherical oxides or complex nanostructures; and the synthesis of non-oxide compounds such as nitrides, borides and sulfides via multi-component/multi-phase reactions. The review highlights how the unique plasma environment overcomes the limitations of conventional methods, enabling rapid, efficient and controllable fabrication of materials, with promising yield and scalability for applications. Finally, perspectives on fundamental mechanisms, intelligent process control and industrialization challenges—supported by a techno-economic analysis highlighting its strategic positioning for high-value products despite high capital expenditure—are discussed to guide future development in this dynamic field.
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