《超重力反应工程》是一本极具权威性与实用性的综合性参考书籍，系统且全面地呈现了超重力反应工程的基本原理及其在工业领域的广泛应用。书中从分子化学工程视角出发，深入剖析 超重力反应过程强化的科学内涵、核心原理、实施方法及实际应用场景，构建起从微观分子到宏观工厂应用的完整知识体系。同时，对超重力反应器的流体动力学行为、设计准则与方法，以及新型多相反应过程和反应结晶技术进行了重点阐释。??
本书融合多学科知识，内容丰富，适用于化学工程、能源化学工程、化工机械、环境工程和材料工程等领域的科研人员、技术工作者、教师和学生参考。

陈建峰 中国工程院院士，北京化工大学教授、博士生导师。长期从事纳米材料和超重力技术领域的研究。在国际上率先提出并开拓了超重力反应工程新领域，并实现大规模工业应用，为我国超重力技术由合作跟踪到国际工业引 领的转变做出了突出贡献。作为第 一完成人，获国家技术发明奖二等奖2项、国家科技进步奖二等奖1项，另作为主要完成人获国家技术发明奖二等奖、国家专利金奖和国家 级教学成果奖一等奖各1项等。

1. Introduction to high-gravity reaction engineering 1 1.1 Introduction to chemical reaction engineering 1 1.2 High-gravity intensification technology 2 1.3 High-gravity reaction engineering 5 1.4 Future development 12 References 16 2. Hydrodynamic behavior in high-gravity reactors 19 2.1 Phenomena and description of fluid flow in high-gravity reactors 19 2.2 Characteristic parameters of fluid flow in high-gravity reactors 23 2.3 Liquid holdup in high-gravity reactors 39 2.4 The residence time of liquid in high-gravity reactors 45 References 47 3. Design principles and methods of high-gravity reactors 49 3.1 General design information of high-gravity reactors 49 3.2 Structural design of high-gravity reactors 51 3.3 High-gravity reactor power calculation 56 3.4 High-gravity reactor structure 57 References 65 4. Liquid-liquid reaction system enhancement by high-gravity technology and engineering application 67 4.1 Molecular mixing and its modeling 68 4.2 Enhancement of high-gravity condensation reaction and industrial application 85 4.3 Enhancement of high-gravity sulfonation reaction and industrial application 94 4.4 High-gravity enhanced polymerization 106 4.5 Enhancement of high-gravity alkylation reaction 115 4.6 Enhanced halogenation reaction by high-gravity technology 126 References 138 5. Reaction enhancement and industrial application of high-gravity technology in gas-liquid system 141 5.1 Mass transfer behavior and modeling in high-gravity reactors 142 5.2 High-gravity reaction absorption technology 158 5.3 High-gravity enhanced reaction and separation coupling technology 191 5.4 High-gravity oxidation reaction technology 195 References 201 6. High-gravity reaction engineering of gas-solid system 207 6.1 Visualization of hydrodynamic characteristics of gas-solid multiphase system in high-gravity reactors 208 6.2 CFD simulation of gas-phase flow in RPBs 219 6.3 Research and application of high-gravity catalytic reaction in gas-solid system 243 References 255 7. High-gravity reaction engineering of gas-liquid-solid system 257 7.1 CO2 absorption in K2CO3/KHCO3 solution enhanced by the organic phase in high-gravity reactors 258 7.2 α-Methylstyrene (AMS) catalytic hydrogenation under high-gravity environment 266 7.3 Hydrogen peroxide production by the high-gravity anthraquinone process 268 7.4 High-gravity catalytic oxidation for sulfur removal 274 7.5 High-gravity biochemical reaction 279 References 288 8. High-gravity reactive crystallization and its industrial application 291 8.1 Basic principles of nanomaterial preparation by high-gravity reactive crystallization 293 8.2 Preparation of nanopowders by gas-liquid-solid high-gravity reactive crystallization 296 8.3 Nanopowder preparation by gas-liquid high-gravity reactive crystallization 303 8.4 Nanopowder preparation by liquid-liquid high-gravity reactive crystallization 311 8.5 Scale production of nanopowders by high-gravity method 326 8.6 Preparation and application of nanodispersions by high-gravity reactive crystallization and extractive phase transfer 328 References 350 Index 355