High Entropy Materials covers the fundamental concepts of these materials and their emerging applications. To fulfil growing energy demand, scientists are looking for novel materials which can be used for the fabrication of high-performance energy devices.
High Entropy Materials covers the fundamental concepts of these materials and their emerging applications. To fulfil growing energy demand, scientists are looking for novel materials which can be used for the fabrication of high-performance energy devices.
Dr. Anuj Kumar is an Assistant Professor at GLA University, Mathura, India. His research focus is on molecular as well M-N-C electrocatalysts for H2, O2, and CO2 involving electrocatalysis, nanomaterials, nanocomposites, fuel cells, water electrolyzers, nano-sensors, bio-inorganic chemistry, macrocyclic chemistry. He is serving as Section Editor, Guest editor, and editorial board member for various journals. Dr. Ram Gupta is a Professor at Pittsburg State University. Before joining Pittsburg State University, he worked as an Assistant Research Professor at Missouri State University, Springfield, MO then as a Senior Research Scientist at North Carolina A&T State University, Greensboro, NC. He is serving as Associate Editor, Guest editor, and editorial board member for various journals.
Inhaltsangabe
1 Introduction to High Entropy Materials 2 A Brief History of High Entropy Materials 3 Synthesis Strategies for the Preparation of High-Entropy Materials 4 High Entropy Materials: Composition and Structural Aspects 5 Mathematical Modeling for High Entropy Materials 6 Characterizations of High Entropy Materials 7 Stability Landscape and Charge Compensation Mechanism for Isovalent and Aliovalent Substitution in High Entropy Oxides 8 Mechanical and Electrical Properties of High Entropy Materials 9 High Entropy Materials for Methanol Oxidation Reactions 10 High Entropy Materials for Electrocatalytic Hydrogen Generation 11 High Entropy Materials for Oxygen Evolution Reactions 12 High Entropy Materials for Oxygen Reduction Reactions 13 High Entropy Materials for Oxygen Reduction Reaction 14 High Entropy Materials for CO2 Conversion 15 High Entropy Materials as Electrodes for Supercapacitors 16 High Entropy Materials as Anode in Li-Ion Battery 17 High Entropy Materials for Hydrogen Storage 18 High Entropy Materials for Flexible Devices 19 High Entropy Materials for Electrochemical Sensors 20 Thermo - Hydraulic Performance and Entropy Generation Analysis of Nanofluids in Heat Exchanger 21 Tribological Properties of High Entropy Materials 22 High Entropy Materials for Thermoelectric Applications 23 High Entropy Materials for Thermal and Electromagnetic Protection Index
1 Introduction to High Entropy Materials 2 A Brief History of High Entropy Materials 3 Synthesis Strategies for the Preparation of High-Entropy Materials 4 High Entropy Materials: Composition and Structural Aspects 5 Mathematical Modeling for High Entropy Materials 6 Characterizations of High Entropy Materials 7 Stability Landscape and Charge Compensation Mechanism for Isovalent and Aliovalent Substitution in High Entropy Oxides 8 Mechanical and Electrical Properties of High Entropy Materials 9 High Entropy Materials for Methanol Oxidation Reactions 10 High Entropy Materials for Electrocatalytic Hydrogen Generation 11 High Entropy Materials for Oxygen Evolution Reactions 12 High Entropy Materials for Oxygen Reduction Reactions 13 High Entropy Materials for Oxygen Reduction Reaction 14 High Entropy Materials for CO2 Conversion 15 High Entropy Materials as Electrodes for Supercapacitors 16 High Entropy Materials as Anode in Li-Ion Battery 17 High Entropy Materials for Hydrogen Storage 18 High Entropy Materials for Flexible Devices 19 High Entropy Materials for Electrochemical Sensors 20 Thermo - Hydraulic Performance and Entropy Generation Analysis of Nanofluids in Heat Exchanger 21 Tribological Properties of High Entropy Materials 22 High Entropy Materials for Thermoelectric Applications 23 High Entropy Materials for Thermal and Electromagnetic Protection Index
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