Note: Cover -- Title Page -- Copyright Page -- Contents -- List of Contributors -- Preface -- About the Companion Website -- Dedication -- Part I High-Temperature/Deep Earth Processes -- Chapter 1 High-Temperature Kinetic Isotope Fractionation of Silicate Materials -- 1.1. Introduction -- 1.2. Diffusion in Multi-Component Condensed Systems: Theory and Definitions -- 1.2.1. Fick's Laws and the Diffusion Matrix -- 1.2.2. Effective Binary Diffusion Coefficients -- 1.2.3. Self-Diffusion Coefficients -- 1.2.4. Thermal (Soret) Diffusion Coefficients -- 1.3. Kinetic Isotope Fractionation During Diffusion Between Natural Melts -- 1.3.1. Laboratory Experiments Documenting Ca Isotope Fractionation by Diffusion Between Molten Rhyolite and Basalt -- 1.3.2. Isotope Fractionation between Melts from a Natural Setting -- 1.4. Isotope Fractionation by Soret Diffusion -- 1.4.1. The Soret Coefficient -- 1.4.2. Soret Isotope Fractionation in Silicate Liquids -- 1.5. Isotope Fractionation by Diffusion in Silicate Minerals -- 1.5.1. Experiments documenting Lithium Isotopic Fractionation by Diffusion in Pyroxene -- 1.5.2. Natural Examples of Lithium Zoning and Isotopic Fractionation by Diffusion in Pyroxenes -- 1.5.3. Lithium Isotopic Fractionation by Diffusion in Olivine -- 1.5.4. Fe-Mg zoning and Fe and Mg Isotopic Fractionation in Olivine -- 1.6. Isotope Fractionation by Evaporation from Silicate Melts -- 1.6.1. The Hertz-Knudsen Evaporation Equation -- 1.6.2. Rayleigh Fractionation -- 1.6.3. High-Temperature Vacuum Evaporation Experiments -- 1.6.4. Evidence of Evaporation in Natural CAIs from Chondritic Meteorites -- 1.7. Summary -- 1.8. Thoughts on Further Research -- References -- Chapter 2 Ca and K Isotope Fractionation by Diffusion in Molten Silicates: Large Concentration Gradients Are Not Required to Induce Large Diffusive Isotope Effects -- 2.1. Introduction. , 2.2. Methods -- 2.2.1. Experiments -- 2.2.2. Electron Microprobe Analyses -- 2.2.3. Ca Isotopic Measurements -- 2.2.4. K Isotopic Measurements -- 2.3. Results -- 2.3.1. Major Element Diffusion Profiles -- 2.3.2. Ca and K Isotopes -- 2.4. Discussion -- 2.5. Modeling -- 2.5.1. General Multicomponent Diffusion -- 2.5.2. The Zhang (1993) Modified Effective Binary Diffusion Model -- 2.5.3. Comparison to Previous Studies -- 2.6. Conclusions and Possible Future Applications -- Appendix Linear versus exponential dependence of activity on SiO2 -- Acknowledgments -- References -- Chapter 3 Calcium Isotope Constraints on Recycled Carbonates in Subduction-Related Magmas -- 3.1. Introduction -- 3.2. Analytical Methods and Samples -- 3.2.1. Double-spike Thermal Ionization Mass Spectrometry Calcium Isotope Measurements -- 3.2.2. Igneous Samples Characterized for Calcium Isotope Composition -- 3.3. Results -- 3.4. Discussion -- 3.4.1. Calcium Isotopic Record of Marine Carbonates -- 3.4.2. Calcium Isotopic Record of Mantle-Derived Rocks -- 3.4.3. Calcium Isotopes Exhibit no Evidence for Carbonate Sediment Recycling at Subduction Zones -- 3.4.4. Mantle Source(s) of Calcium in Carbonatite Magmas -- 3.4.5. Origin of the Light Calcium Isotope Composition of Laacher See and other Intrusive Carbonatites -- 3.5. Conclusions -- Acknowledgments -- References -- Chapter 4 Reassessing the Role of Continental Lithospheric Mantle in Cenozoic Magmatism, Southwestern North America -- 4.1. Introduction -- 4.2. Geologic Background & -- General Terminology -- 4.2.1. Cenozoic Geologic History of SWNA -- 4.2.2. Definition of Continental Lithospheric Mantle -- 4.3. Methods/Data -- 4.4. Results -- 4.5. Discussion -- 4.5.1. Do Nd Isotope Data Support a CLM Source for Mafic Volcanic Rocks in SWNA? -- 4.5.2. Isotopic Composition of CLM from Xenolith Studies. , 4.5.3. Cenozoic Metasomatism of CLM -- 4.5.4. Physical Evolution of Deep Lithosphere -- 4.6. Conclusions -- Acknowledgments -- References -- Chapter 5 Rhyolite Ignimbrite Generation in the Northern Andes: The Chalupas Caldera, Ecuador -- 5.1. Introduction -- 5.2. Geological Setting and Age of the Chalupas Caldera -- 5.3. Geochemical Results -- 5.3.1. Analytical Techniques -- 5.3.2. Major Element Geochemistry -- 5.3.3. Trace Element Geochemistry -- 5.3.4. Isotope Geochemistry -- 5.3.5. Metamorphic Basement Rocks of the Eastern Cordillera -- 5.4. Evolution of the Chalupas Magmatic System -- 5.4.1. Role of Fractional Crystallization -- 5.4.2. The Role of Crustal Assimilation -- 5.4.3. Modeling Results -- 5.4.4. Model Discussion -- 5.4.5. Assimilation and Crustal Thickness -- 5.5. Crustal Structure, Magma Supply, and Transport -- 5.5.1. Crustal and Magma Density -- 5.5.2. Temperature Considerations -- 5.5.3. Subduction Zone Magma Supply and Magmatic Timescales -- 5.5.4. Timescales of Transport and Assimilation -- 5.6. Chalupas Eruption Volume and Magma Supply -- 5.7. Summary and Conclusions -- Appendix 5A Ar-Ar Geochronology -- Pre-Caldera Lavas -- Chalupas Ignimbrite -- Post-Caldera Lavas -- Summary of Age Data -- Appendix 5B Mineral Chemistry and Petrographic Descriptions -- 5B.1. Pre-Caldera Lavas -- 5B.2. Post-Caldera Lavas -- 5B.3.Chalupas Ignimbrite -- 5B.4. Lithics from the Chalupas Ignimbrite -- Appendix 5C Models for Crystal Fractionation, Assimilation-Fractional Crystallization, and Magma Fluxes -- 5C.1. Quantitative Estimation of Crystal Fractionation Effects -- 5C.2. Assimilation-Fractional Crystallization (AFC) Model Details -- 5C.3. Relationship between f and Crustal Fraction (fc) in the AFC Model -- 5C.4. Magma Supply Considerations -- 5C.5. Magma Supply Requirements -- 5C.6. Diapir Formation and Transport through the Lower and Mid-Crust. , ACKNOWLEDGMENTS -- REFERENCES -- Chapter 6 Xenolith Constraints on "Self-Assimilation" and the Origin of Low 18O Values in Mauna Kea Basalts -- 6.1. Introduction -- 6.2. Samples and Analytical Methods -- 6.2.1. EPMA Analysis of Mineral Major Element Composition -- 6.2.2. Clinopyroxene Trace Element Analysis by LA-ICP-MS -- 6.2.3. Oxygen Isotope Analysis by Laser Fluorination Gas Source Mass Spectrometry -- 6.2.4. Strontium-Nd-Pb Isotope Analysis by TIMS and MC-ICP-MS -- 6.3. Results -- 6.4. Discussion -- 6.4.1. Constraints on Parental Melts of Mauna Kea Xenoliths -- 6.4.2. Constraints on The P-T Conditions Of Xenolith Formation and Later Re-Equilibration -- 6.4.3. Role of Pacific Crust Assimilation and Edifice Self-Assimilation -- 6.4.4. Oxygen Isotope Compositional Variability in the Hawaiian Plume? -- 6.4.5. Significance of Self-Assimilation for Interpretation of Geochemical Signatures in Hawaiian Basalts -- 6.5. Conclusions -- Acknowledgments -- References -- Chapter 7 Monitoring Volcanic Activity Through Combined Measurements of CO2 Efflux and (222Rn) and (220Rn) in Soil Gas: An Application to Mount Etna, Italy -- 7.1. Introduction -- 7.2. Background -- 7.2.1. Mt. Etna Volcanic Activity During 2006 to 2009 -- 7.2.2. Prior Work Utilizing Coupled 220Rn/222Rn and CO2 Efflux Measurements on Mt. Etna -- 7.3. Sampling Strategy and Analytical Methods -- 7.3.1. Sampling Strategy -- 7.3.2. Soil 222Rn and 220Rn Measurements -- 7.3.3. Soil CO2 Concentration and Efflux Measurements -- 7.3.4. Carbon Isotope Measurements -- 7.4. Synopsis of This Study's Results -- 7.4.1. Coupled CO2 Efflux and (220Rn/222Rn) -- 7.4.2. Carbon Isotopes -- 7.5. The Soil Gas Disequilibrium Index (SGDI) -- 7.6. Relationship Between Filtered SGDI Data and Volcanic Activity of Mt. Etna -- 7.6.1. Modelling -- 7.6.2. Comparison of SGDI to Other Monitoring Proxies -- 7.7. Summary. , Appendix Statistical Treatment of SGDI Data -- Cluster Analysis and Spatial Distributions -- Analysis of SGDI Time Series -- Definition of Anomalies in the SGDI Time Series -- Acknowledgments -- References -- Part II Low-Temperature/Shallow Earth Processes -- Chapter 8 The Carbon Isotope Record and Earth Surface Oxygenation -- 8.1. Introduction -- 8.2. The Carbon Isotope Budget -- 8.3. forg and the Oxygen Budget -- 8.4. Oxygen Sinks in a Low-Oxygen World -- 8.4.1. Carbon as a Precambrian Oxygen Sink -- 8.4.2. Sulfur as a Precambrian Oxygen Sink -- 8.4.3. Iron as a Precambrian Oxygen Sink -- 8.4.4. Other Precambrian Oxygen Sinks -- 8.5. Resolving the pO2 - forg Paradox -- 8.6. Predictions of the Authigenic Feedback Hypothesis -- 8.7. Conclusions -- References -- Chapter 9 Detrital Garnet Geochronology: A New Window into Ancient Tectonics and Sedimentary Provenance -- 9.1. Introduction and Motivation -- 9.2. Theoretical Feasibility of Detrital Garnet Geochronology -- 9.2.1. Age Precision vs. Single Garnet Grain Diameter -- 9.2.2. Age Accuracy: Blanks -- 9.2.3. Age Accuracy: Second Point on the Isochron -- 9.3. Detailed Methodology -- 9.3.1. Sample Processing Prior to Chemical Analysis -- 9.3.2. Partial Dissolution: Leaching out the Inclusions -- 9.3.3. Full Dissolution of Pure Garnet Residue -- 9.3.4. Column Chemistry -- 9.3.5. Thermal Ionization Mass Spectroscopy -- 9.3.6. Blank Correction -- 9.3.7. Age Determination -- 9.4. Case Studies -- 9.4.1. Preliminary Work: Multi-Grain Detrital Garnet Ages in Beach Sand from Hampton Beach, New Hampshire -- 9.4.2. Bulk vs. Detrital Garnet Methodology Test: Townshend Dam, Vermont -- 9.4.3. Single-Grain Detrital Garnet Ages in Stream Alluvium: Townshend Dam, Vermont -- 9.4.4. Single-Grain Detrital Garnet in Stream Alluvium: Southern Appalachians -- 9.4.5. Dating Detrital Garnet in Sedimentary Rocks: Scotland. , 9.5. Conclusion.

Note: Cover -- Half-title -- Title page -- Copyright information -- Contents -- Acknowledgments -- 1 Introduction -- 1.1 Background -- 1.1.1 China's Climate Progress Prior to the Paris Agreement -- 1.1.2 How Will China Actually Reduce Emissions beyond 2030, Given Their Current Dependence on Coal for Electricity Generation? -- 1.1.3 Three Pathways -- 1.2 Chapters Overview -- 1.2.1 Electric Utilities -- 1.2.2 Coal -- 1.2.3 Renewables -- 1.2.4 Local Air Pollution -- 1.2.5 Nuclear Power -- 1.2.6 Electric Vehicles -- 1.3 Conclusions -- References -- 2 Reforming China's Electricity Market to Facilitate Low-Carbon Transition -- 2.1 Introduction -- 2.2 Future Trends and Challenges in China's Electricity System -- 2.3 Power Sector Governance -- 2.4 Key Policy Questions -- 2.4.1 System Operation -- 2.4.2 Electricity Pricing -- 2.4.3 Design and Planning of Transmission Networks -- 2.4.4 Pricing Externalities: Cap-and-Trade and Carbon Tax Policies -- 2.5 Policy Recommendations -- 2.5.1 Competitive Wholesale Market with Nondiscriminatory System Operators -- 2.5.2 Devising Pricing Mechanisms to Facilitate Decarbonization -- 2.5.3 Integrated Planning in Transmission and Generation Construction -- 2.5.4 Coordinating Electricity Policies with Low-Carbon Policies -- 2.6 Conclusions -- References -- 3 Promoting Large-Scale Deployment and Integration of Renewable Electricity -- 3.1 Introduction -- 3.2 Current Governance Structure and Policies -- 3.3 Key Considerations for Integrating Large-Scale Renewables into China's Power System -- 3.3.1 Geographic Mismatch between Renewable Resources and Demand Centers -- 3.3.2 Current Pattern: Concentrated Renewable Development in Resource-Rich Regions -- 3.3.3 Recent Trend: Increased Renewable Development Closer to Demand Centers -- 3.3.4 Experience in Other Countries to Deal with the Geographic Mismatch. , 3.3.5 System Flexibility Concerns -- 3.3.6 Greater Demands on Conventional Generators -- 3.3.7 Flexibility of the Network -- 3.3.8 Experience in Other Countries to Improve System Flexibility -- 3.4 Elements of Foundations for a High-Renewable System in China -- 3.4.1 Flexible Conventional Generators -- 3.4.1.1 Designs and Retrofits for Flexible Operation -- 3.4.1.2 Improved Integration and Flexibility of Coupled Heating Systems -- 3.4.1.3 Markets and Incentives: Pathways to Flexible Operation -- 3.4.2 Appropriately Large and More Integrated Transmission Network -- 3.4.2.1 Managing Variability with Appropriate Interconnection -- 3.4.2.2 Regulating Long-Lived Assets for Future Scenarios -- 3.4.2.3 Markets, Operations, and Regulations for Flexibility -- 3.4.3 Storage Technology Development -- 3.4.3.1 Available Storage Technologies at Present -- 3.4.3.2 Policies to Facilitate R& -- D and Deployment -- 3.4.4 Demand-Side Flexibility/Responsiveness -- 3.4.4.1 Value of Demand-Side Measures (DSM) for a High-Renewable System -- 3.4.4.2 Current Developments and Challenges of DSMs in China -- 3.5 Conclusions -- Notes -- References -- 4 Enabling a Significant Nuclear Role in China's Decarbonization: Loosening Constraints, Mitigating Risks -- 4.1 Introduction -- 4.2 China's Current Nuclear Energy Picture and the Scale of the Challenge -- 4.3 Avoiding Catastrophe: Safety and Security -- 4.3.1 Safety -- 4.3.1.1 Strengthening Safety: Policies -- 4.3.1.2 Addressing Accident Risks: Technologies and Business Models -- 4.3.2 Security -- 4.3.2.1 Strengthening Security: Policies -- 4.3.2.2 Strengthening Security: Technologies and Business Models -- 4.4 Building Public Trust: Siting and Public Acceptance -- 4.4.1 Addressing the Siting and Public Acceptance Constraint: Policies. , 4.4.2 Addressing the Siting and Public Acceptance Constraint: Technologies and Business Models -- 4.5 Improving Economics -- 4.5.1 Addressing the Economic Constraint: Policies -- 4.5.2 Addressing the Economic Constraint: Technologies and Business Models -- 4.6 More Modest Constraints -- 4.6.1 Waste Management -- 4.6.2 Proliferation Resistance -- 4.6.3 Government and Industrial Capacity -- 4.6.4 Regulatory Delays -- 4.6.5 Integrating Nuclear Energy into China's Evolving Energy Infrastructure -- 4.7 Unlikely to Be a Major Constraint: Uranium Supply -- 4.8 China's Investments in Advanced Nuclear Systems -- 4.8.1 Chinese-Designed Sodium-Cooled Fast Reactors -- 4.8.2 High-Temperature Pebble-Bed Reactors -- 4.8.3 Molten Salt Reactors -- 4.8.4 Terrapower -- 4.8.5 Lead-Cooled Fast Reactors -- 4.8.6 Accelerator-Driven Systems -- 4.8.7 Fusion Reactors -- 4.9 Conclusions -- 4.9.1 Avoiding Catastrophes -- 4.9.2 Building Public Trust -- 4.9.3 Improving Economics -- 4.9.4 Avoiding Technological Lock-in on Dangerous and Unneeded Technologies -- 4.9.5 Developing Options for the Future -- 4.9.6 The Path Ahead -- Notes -- References -- 5 Transitioning to Electric Vehicles -- 5.1 Introduction -- 5.2 Energy Security -- 5.3 Traffic Congestion -- 5.4 Air Pollution -- 5.5 Trade and Manufacturing -- 5.6 Deploying Electric Vehicles -- 5.7 What about CO2? -- 5.8 Magnitude of Transition -- 5.9 Is Electrification of China's Vehicle Fleet the Optimal Path for China? -- 5.10 Will Electrification of the Vehicle Fleet Result in CO2 Emission Reductions? -- 5.11 Realizing Deeper Deployment of EVs -- 5.12 EVs: The Vehicle of Choice? -- 5.13 Freight Transport -- 5.13.1 Can China Convert Trucks to Electricity? -- 5.14 What Are the Economic Challenges to Passenger EV Penetration? -- 5.15 Charging Infrastructure -- 5.16 Home Charging -- 5.16.1 Fast-Charging Stations. , 5.17 Will the Growth in Renewables Affect the Economics of Electric Cars? -- 5.18 Are There Reasonable Scenarios in Which Electrifying the Transportation Sector Fails? -- 5.19 Conclusions -- Notes -- References -- 6 From Barrier to Bridge: The Role of Coal in China's Decarbonization -- 6.1 Introduction -- 6.2 Rise of China's Coal Industry -- 6.2.1 Key Pillars of Industrialization and Urbanization -- 6.2.2 Early Energy Conservation Efforts -- 6.2.3 New Drivers for Substitutes -- 6.3 Politics of Coal and the Grid -- 6.3.1 Planning Coal Electricity amid Broader Liberalization -- 6.3.2 Local Government Incentives -- 6.3.3 Grid Company Incentives -- 6.4 Rewiring the Coal Generation Fleet -- 6.4.1 Engineering Challenges of Flexible Operation -- 6.4.2 Economics of Flexible Operation -- 6.4.3 Retrofits and Markets: An Uncertain Future -- 6.4.4 Carbon Capture, Utilization, and Sequestration (CCUS) -- 6.5 Direct Coal Use: The Other Half of the Challenge -- 6.5.1 Overview of Direct Coal Use -- 6.5.2 Iron and Steel Sector -- 6.6 Conclusions: Opportunities for the Coal ''Bridge'' -- 6.6.1 Technology Recommendations -- 6.6.2 Economic and Political Institution-Building Recommendations -- 6.6.3 Socioeconomic Impacts and Missing Policy Debate -- 6.6.3.1 Make Transition Plans for Stranded Costs During Electricity Market Introduction -- 6.6.3.2 Address Distributional Impacts between Provinces with Different Generation and Industrial Mixes -- 6.6.3.3 Establish Criteria and Expand Funding to Social Welfare and Job Displacement Assistance -- 6.6.3.4 Study and Address Equity Considerations of Coal Power and Industry Relocation -- Notes -- References -- 7 Coordinating Strategies to Reduce Air Pollution and Carbon Emissions in China -- 7.1 Introduction -- 7.2 Background -- 7.2.1 Overview of Air Pollution and Carbon Mitigation Efforts in China. , 7.2.2 Governance Structure for Air Pollution and Climate Issues in China -- 7.3 Synergies and Trade-offs between Air Pollution and Carbon Mitigation Strategies -- 7.3.1 Examples of Win-Win Policies -- 7.3.1.1 Carbon Pricing -- 7.3.1.2 Renewable Energy Policies -- 7.3.1.3 Energy Efficiency Measures -- 7.3.2 Examples of Air Pollution Control Strategies with Potential Climate Penalties -- 7.3.2.1 Synthetic Natural Gas Development -- 7.3.2.2 Transport and Residential Electrification -- 7.4 Foundations for Long-Term Decarbonization -- 7.5 Conclusion -- Notes -- References -- 8 Conclusion -- Index.