Engineering Solutions for CO2 Conversion. Группа авторов
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Table of Contents
1 Cover
2 Engineering Solutions for CO2 Conversion
4 1 CO2 Capture – A Brief Review of Technologies and Its Integration 1.1 Introduction: The Role of Carbon Capture 1.2 CO2 Capture Technologies 1.3 Integration of Post‐combustion CO2 Capture in the Power Plant and Electricity Grid 1.4 CO2 Capture in the Industrial Sector 1.5 Conclusions References Notes
5 2 Advancing CCSU Technologies with Computational Fluid Dynamics (CFD): A Look at the Future by Linking CFD and Process Simulations 2.1 Sweep Across the General Simulation Techniques Available 2.2 Multi‐scale Approach for CFD Simulation of Amine Scrubbers 2.3 Eulerian, Eulerian–Lagrangian, and Discrete Element Methods for the Simulation of Calcium Looping, Mineral Carbonation, and Adsorption in Other Solid Particulate Materials 2.4 CFD for Oxy‐fuel Combustion Technologies: The Application of Single‐Phase Reactive Flows and Particle Tracking Algorithms 2.5 CFD for Carbon Storage and Enhanced Oil Recovery (EOR): The Link Between Advanced Imaging Techniques and CFD 2.6 CFD for Carbon Utilization with Chemical Conversion: The Importance of Numerical Techniques on the Study of New Catalysts 2.7 CFD for Biological Utilization: Microalgae Cultivation 2.8 What Does the Future Hold? References
6 3 Membranes Technologies for Efficient CO2 Capture–Conversion 3.1 Introduction 3.2 Polymer Membranes 3.3 Oxygen Transport Membranes for CO2 Valorization 3.4 Protonic Membranes 3.5 Membranes for Electrochemical Applications 3.6 Conclusions and Final Remarks References
7 4 Computational Modeling of Carbon Dioxide Catalytic Conversion 4.1 Introduction 4.2 General Methods for Theoretical Catalysis Research 4.3 Characterizing the Catalyst and Its Interaction with CO2 Using DFT Calculations 4.4 Microkinetic Modeling in Heterogeneous Catalysis 4.5 New Trends: High‐Throughput Screening, Volcano Plots, and Machine Learning References
8 5 An Overview of the Transition to a Carbon‐Neutral Steel Industry 5.1 Introduction 5.2 Global Relevance of the Steel Industry 5.3 Current Trends in Emission Policies in the World's Leading Countries in Steel Industry 5.4 Transition to a Carbon‐Neutral Production. A Big Challenge for the Steel Industry 5.5 CO2 Methanation: An Interesting Opportunity for the Valorization of the Steel Industry Emissions 5.6 Relevant Projects Already Launched for the Valorization of the CO2 Emitted by the Steel Industry 5.7 Concluding Remarks References
9 6 Potential Processes for Simultaneous Biogas Upgrading and Carbon Dioxide Utilization 6.1 Introduction 6.2 Overview of Biogas General Characteristics and Upgrading Technologies to Bio‐methane Production 6.3 CCU Main Technologies 6.4 Potential Processes for Biogas Upgrading and Carbon Utilization 6.5 Conclusions References
10 7 Biogas Sweetening Technologies 7.1 Introduction 7.2 Biogas Purification Technologies 7.3 Biogas Upgrading Technologies 7.4 Conclusions References
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8 CO2 Conversion to Value‐Added Gas‐Phase Products: Technology Overview and Catalysts Selection
8.1 Chapter Overview