Handbook of Climate Change Mitigation and Adaptation

Now in its 3^rd edition, this extensively revised and significantly expanded handbook addresses important new research findings and the global need for action.

There is a growing consensus that anthropogenic activities have been driving global climate change and the consequence will be catastrophic for civilization. Reducing the 37.1 billion metric tons of CO₂ produced annually (2017 global emissions) along with other greenhouse gases has become a leading grand challenge and the pursuit of sustainable energy, environments and economies is a complex issue affecting the daily life of every citizen.

The Handbook of Climate Change Mitigation and Adaptation collates information in this multi-disciplinary area, providing readers with a comprehensive overview on the scientific background and current technologies. Intended for an interdisciplinary, global audience of researchers at universities and in industry, it covers climate change models; established, mature and promising future technologies and ideas; the impact of climate change; strategies for dealing with global warming; the related political frameworks; and climate education.  

• Climate Change Impact
• Fuel Cells
• Greenhouse Gases
• Renewable Energy
• Sea-level Rise
• Climate Change Solutions
• CO2 Emission
• Carbon Capture and Storage (CCS)
• Water Scarcity
• Deforestation

• Circe Biotechnologie GmbH, Vienna, Austria

  Maximilian Lackner

• Mewbourne School of Petroleum and Geological Engineering, University of Oklahoma, Norman, USA

  Baharak Sajjadi

• Department of Chemical Engineering, University of Mississippi, University, USA

  Wei-Yin Chen

Dr. Maximilian Lackner is study programme director of the Master “Innovation and Technology Management” and “International Business and Engineering” at the University of Applied Sciences FH Technikum Wien, Vienna, Austria. He has obtained his PhD in technical chemistry from Vienna University of Technology, Vienna, Austria, in 2003 and his habilitation in chemical engineering from Vienna University of Technology, Vienna, Austria, in 2009. Dr. Lackner in docent at Vienna University of Technology, Vienna, Austria, Johannes Kepler University, Linz, Austria and Xidian University, Xi’An, China. Having founded 6 companies, Dr. Lackner has more than 15 years of professional experience in the polymer industry in various senior leadership positions in Austria and China. His research interests include biopolymers, in-situ brownfield remediation technologies, process systems engineering and industrial engineering. Dr. Lackner has authored over 100 scientific publications. He is founding editor-in-chief of the International Journal of Biobased Plastics.

Dr. Baharak Sajjadi is an assistant professor of Petroleum and Geological Engineering in the Mewbourne College of Earth and Energy at the University of Oklahoma, USA. She has obtained her PhD in chemical engineering from the University of Malaya, Malaysia, in 2015, and has served as a research assistant professor of Chemical Engineering at the University of Mississippi, USA. She has over 10 years of research experience in advanced refinery processes and bioprocesses, carbon conversion and modification technologies, renewable energies, and computational fluid dynamics (CFD simulation). Dr. Sajjadi has published over 50 scientific articles in peer-reviewed journals. She pioneered the use of ultrasound, non-thermal plasma, and chemical methods for carbon capture and conversion, natural gas conversion, and other environmental applications.

Dr. Wei-Yin Chen is a professor emeritus of Chemical Engineering of the University of Mississippi. He has had over 40-years of experience in developing technologydriven, knowledge-based, carbon conversion programs for in-furnace NO reduction, coal liquefaction, and low-temperature carbon modifications for sustainable food, energy, and water nexus. He founded and has been leading the Sustainable Energy and Environmental Group (SEEG) with over 250 collaborators around the globe. The SEEG pioneered the use of ultrasound, light, non-thermal plasma, biological, and chemical methods to modify the material surface for carbon gasification, carbon activation for CO2 capture and wastewater treatment, soil amendment, electrode fabrication, desalination/deionization, biomedical material, fuel cell, etc. He has been awarded by UM and national and international organizations for his contributions to research, teaching, and services. He has served as a reviewer or panelist for institutions around the globe. 

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