Low-temperature Activation and Catalytic Transformation of Methane to Non-CO2 Products

Informationen zum Autor Franklin Tao, PhD and Professor of Chemistry and Chemical Engineering is an elected fellow of the American Association for the Advancement of Science (AAAS) and the Royal Society of Chemistry (RSC) at the University of Kansas. He published over 200 research articles on heterogeneous catalysis for methane transformation, single-atom catalysis, surface chemistry, dynamcis of catalyst structure, in situ/operando characterization methods, and instrumentations. Klappentext "Methane is an abundant resource with harmful environmental impacts. Consequently, the transformation of methane into chemical and fuel feedstocks is highly attractive, but historically this process has required energy-intensive, high temperature conditions to achieve selective dissociation of C-H bonds. Recently significant progress has been made in achieving low-temperature methane conversion, offering access to value-added chemicals and fuels under mild conditions for energy-efficient chemical synthesis and climate remediation."--

Auteur

Franklin Tao, PhD and Professor of Chemistry and Chemical Engineering is an elected fellow of the American Association for the Advancement of Science (AAAS) and the Royal Society of Chemistry (RSC) at the University of Kansas. He published over 200 research articles on heterogeneous catalysis for methane transformation, single-atom catalysis, surface chemistry, dynamcis of catalyst structure, in situ/operando characterization methods, and instrumentations.

Texte du rabat

Sustainably tap one of the world's most abundant natural resources with this essential guide Methane is among our crucial natural resources, with myriad applications both domestic and industrial. Atmospheric accumulation of methane, however, is one of the major drivers of climate change. The increasingly urgent search for a sustainable world demands methods for the transformation of methane that maximize its potential as a source of energy and chemical production without a harmful effect on the atmosphere and local environment. Low-Temperature Activation and Catalytic Transformation of Methane to Non-CO2 Products introduces a growing field in chemistry, chemical engineering, and energy sciences. Beginning with an overview of methane formation and its significance in chemical production, the book surveys historical transformations of methane to value-added chemicals and explains why a low-temperature route of methane transformation is necessary and significant. It then discusses existing findings in low-temperature activation and catalytic transformation, including activations with free standing single-atom cations, free standing MO+ clusters, and broadly defined M-O clusters encapsulated in zeolite, and catalytic oxidation by molecular catalysts, metal atoms anchored in zeolites, and metal sites openly exposed on alloy nanoparticles. The book concludes with a chapter discussing current challenges and promising solutions to tackle these challenges. Low-Temperature Activation and Catalytic Transformation of Methane to Non-CO2 Products readers will also find: Coverage of concepts, perspectives, and skills required for those working in this important field in catalysis research. Exemplified experimental and computational results throughout, derived from existing research literature. Detailed discussion of low-temperature transformation methods incorporating catalysts including zeolite, gold-palladium, and many more. Low-Temperature Activation and Catalytic Transformation of Methane to Non-CO2 Products is ideal for experimentalists, researchers, scientists, and engineers working in methane transformation, heterogeneous catalysis, homogeneous catalysis, sustainable chemistry, surface science, climate change mitigation, and related fields.