Note: Intro -- Foreword -- Preface -- Contents -- Contributors -- Introduction -- 1 Atmospheric Haze Pollution in China and Research Background -- 2 Content of Program -- 3 Results of Program -- 4 Outlook -- Atmospheric Oxidation and Secondary Particle Formation -- 1 Regeneration Mechanism of OH Radicals -- 1.1 Establishment of a Technique for Measuring Atmospheric Radicals and Its Integrated Observation Experiment -- 1.2 Characterization of the Key Conversion Process of Radical Sources -- 1.3 Budget Closure Experiments on OH Radicals and Their Regeneration Mechanism -- 1.4 Normalized Analysis of Regeneration Mechanism of OH Radicals -- 1.5 Summary -- 2 Formation Mechanism of Secondary Particles -- 2.1 Process of Atmospheric Oxidation -- 2.2 Formation and Growth of Secondary Fine Particles -- 2.3 Moisture Absorption and Optical Properties of Fine Particles and Their Effects on Forming Haze -- 3 Formation of Secondary Aerosol from Typical Emission Sources -- 3.1 Chamber Simulation of Motor Vehicle Exhaust -- 3.2 Chamber Simulation of Biomass Burning -- 3.3 Chamber Simulation of Cooking Emission -- 4 Formation of Secondary Particles Under Combined Pollution Conditions -- 4.1 Formation of Secondary Particles Under Conditions of Coexisting SO2, NO2 and NH3 -- 4.2 Simulation of NH3, SO2, and Motor Vehicle Exhaust Combined Pollution -- 4.3 Heterogeneous Reaction on the Surface of Black Carbon -- References -- Haze Source Tracing -- 1 Sources of Particulate Matter in the BTHR -- 2 Mechanism of Haze Formation in Beijing -- 3 Effects of Fog Formation on the Physical and Chemical Characteristics of Fine Particles -- 4 Development of the Source Resolution Receptor Model and Analysis of the Heavy Haze Process -- 5 Source Analysis of Aerosol PM2.5 in the BTHR -- 6 Establishment of the National Large Scale Haze Precursor Emission Inventory. , 6.1 Method of Establishing the Key Source Atmospheric Pollutant Emission Inventory -- 6.2 National Large Scale Emission Inventory of Haze Precursor -- 6.3 Spatial, Temporal, and Chemical Species Allocation of Emission Inventories -- 7 Multiscale Nested Emission Inventory of Haze Precursors with High Spatiotemporal Resolution and Key Source Identification -- 7.1 Coupling of the National Inventory and the Regional Inventory -- 7.2 Source Apportionment and Identification of Main Emission Sources in Each Region -- 8 Quantitative Analysis of Sources of Haze-Causing Particles in Beijing -- 8.1 Sensitivity Analysis of Pollutant Source Spectrum -- 8.2 Chemical Species Reconstruction of Particulate Matter -- 8.3 Beijing PM2.5 Pollution Source Analysis -- 8.4 Visualization of PM2.5 Source Analysis -- References -- Numerical Model of Atmospheric Haze -- 1 Numerical Model of Regional Atmospheric Haze -- 1.1 Research and Development of Multi-model Forecasting and Early Warning System for Atmospheric Haze -- 1.2 Research and Development of ChemDAS -- 1.3 Multi-model Ensemble Prediction Technology for Atmospheric Haze -- 1.4 Application Case of Ensemble Forecasting and Early Warning System for Atmospheric Haze -- 1.5 Procedures for Forecasting and Early Warning System for Atmospheric Haze -- 2 Studying PM2.5 Typical Sources in the Background Region Using the Radiocarbon Isotope Method -- 2.1 Establishing the Analytical Method of Carbon Components in PM2.5 Based on 14C -- 2.2 14C Source Analysis and PMF Model Validation -- 3 Quantitative Evaluation of Source Contribution of Important Components in PM2.5 in the BTHR -- 3.1 Regional Sources and Vertical Variations of PM2.5 -- 3.2 Analysis of PM2.5 Industry Sources -- References -- Research and Development, Industrialization, and Application of Advanced Instruments -- 1 Development and Application of the Smog Chamber. , 1.1 Construction Scheme -- 1.2 Characterization of the Smog Chamber System -- 1.3 Research Applications of the Smog Chamber -- 2 Online Measurement Technology of Atmospheric Oxidation (HOx and NO3 Radicals) -- 2.1 LIF System Measuring HOx Radicals -- 2.2 Real-Time CRDS Detection System Monitoring Atmospheric NO3 Radicals -- 2.3 OP-DOAS System Monitoring NO3 Radicals -- 3 Lidar Detection Technology for Monitoring Atmospheric Fine Particles, Water Vapor, and Ozone -- 3.1 Atmospheric Fine Particle Lidar -- 3.2 Ozone Detection Lidar -- 3.3 Raman Water Vapor Lidar -- References -- Multi-pollutant Collaborative Treatment Technology and Special Equipment of Atmospheric Haze -- 1 Development of Key Materials -- 1.1 Preparation of Inorganic Materials for Particulate Removal -- 1.2 Preparation of Critical Catalytic Materials for VOC Treatment -- 1.3 Development of Catalyst for Regenerative Catalytic Oxidation of Special VOC -- 1.4 Development of Photocatalytic Purification Materials for Ambient Pollutants -- 2 Development of Functional Coupling Components -- 2.1 Components and Processes of High-Frequency Electrostatic-Fabric Integrated Dedusting Technology -- 2.2 Dust Removal Performance of External Field Reinforced Conductive Ceramic Tubes -- 2.3 Denitrification Performance of Fiber Ceramic Tubes Supporting Low-Temperature SCR Catalysts -- 3 Demonstration of Industrial Application of Multi-pollutant Coordinated Particular Treatment Device -- 3.1 Development and Application of a Charge-Strengthened Dust Removal Device -- 3.2 Test Results of Charge Strengthened Dust Removal Device -- 4 Effective Control Technology for Atmospheric Pollution Emission from Bulk Coal -- Further Readings -- Index.