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