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200 00$aManagement of extreme situations /$fedited by Pascal Lie?vre, Monique Aubry, Gilles Garel
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330   $aIn response to the rise of various forms of the extreme in economies, organizations and societies (such as disruptive innovation, climate emergency, financial crisis, high-risk sport, etc.), an ambitious 21st century program sets the agenda of management sciences around the unknown, disruption, uncertainty and risk.  Management of Extreme Situations presents the research results from the conference organized at the Cerisy-la-Salle International Cultural Center, France, in 2016. It testifies to the existence of an international community that brings together, around management sciences, various disciplines studying the management concept of extreme situations.  Through the analysis of varied contexts (polar and mountain expeditions, fire rescue services, exploration projects in the military field, creative industries, etc.), this book offers an initial grammar of the extreme. It presents a heuristic for the management of these situations ? particularly in terms of sensemaking, ambidexterity and knowledge expansion.
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200 10$aHigh-entropy materials $efrom basics to applications /$fHuimin Xiang, Fu-Zhi Dai, Yanchun Zhou
210  1$aWeinheim, Germany :$cWiley-VCH GmbH,$d[2023]
210  4$d©2023
215   $a1 online resource (274 pages)
311 08$aPrint version: Xiang, Huimin High-Entropy Materials Newark : John Wiley & Sons, Incorporated,c2023 9783527350353 
320   $aIncludes bibliographical references and index.
327   $aCover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Introduction to High-Entropy Materials -- 1.1 History of High-Entropy Materials -- 1.2 Definition of High-Entropy Materials -- 1.3 Core Effects of HEMs -- 1.3.1 High-Entropy Effect -- 1.3.2 Lattice Distortion -- 1.3.3 Sluggish Diffusion -- 1.3.4 Cocktail Effect -- 1.4 Development of the HEMs -- References -- Chapter 2 Structural Features and Thermodynamics of High-Entropy Materials -- 2.1 Structural Features of High-Entropy Materials -- 2.1.1 Crystal Structure of High-Entropy Alloys -- 2.1.2 Crystal Structure of High-Entropy Ceramics -- 2.1.3 Atomic Distribution -- 2.1.3.1 Atomic Distribution in HEAs -- 2.1.3.2 Atomic Distribution in HECs -- 2.1.4 Lattice Distortion -- 2.2 Electronic Structure and Band Gap Engineering -- 2.2.1 Electronic Structure of HEAs -- 2.2.2 Electronic Structure of HECs -- 2.3 Lattice Dynamics and Phonon Dispersion -- 2.4 Thermodynamics and Phase Formation -- 2.4.1 High-Entropy Alloys -- 2.4.1.1 Thermodynamic Criteria -- 2.4.1.2 Valence Electron Concentration Criteria -- 2.4.1.3 Residual Strain Criteria -- 2.4.2 High-Entropy Ceramics -- 2.4.2.1 Thermodynamic Criteria -- 2.4.2.2 Other Criteria -- References -- Chapter 3 Theoretical Design Aspects in High-Entropy Materials -- 3.1 Introduction -- 3.2 Formability Prediction -- 3.2.1 Empirical Models -- 3.2.2 Thermodynamic Computations -- 3.3 Properties Prediction -- 3.3.1 Lattice Distortions -- 3.3.2 Elastic Properties -- 3.3.3 Stacking Fault Energy -- 3.3.4 Thermal Properties -- 3.3.5 Simulation on Defects -- 3.4 Conclusions and Perspectives -- References -- Chapter 4 Synthesis and Processing of High-Entropy Materials -- 4.1 Powders -- 4.1.1 Powders of HEAs -- 4.1.1.1 Mechanical Alloying -- 4.1.1.2 Atomization -- 4.1.1.3 Wet Chemistry -- 4.1.1.4 Hydrogenation-Dehydrogenation -- 4.1.2 Powders of HECs.
327   $a4.1.2.1 Mechanical Alloy -- 4.1.2.2 Wet Chemistry -- 4.1.2.3 Solid-State Reaction -- 4.2 Dense and Porous Bulks -- 4.2.1 HEAs -- 4.2.2 HECs -- 4.3 Films and Coatings -- 4.3.1 Laser Cladding -- 4.3.2 Spray Techniques -- 4.3.3 Vapor Deposition -- 4.3.3.1 Magnetron Sputtering -- 4.3.3.2 Pulsed Laser Deposition -- 4.4 Other Novel Synthesis and Processing Methods -- 4.4.1 Additive Manufacturing -- 4.4.2 Carbothermal Shock Synthesis -- 4.4.3 Severe Plastic Deformation Process -- References -- Chapter 5 Characterization of High-Entropy Materials -- 5.1 Phase Identification -- 5.2 Elemental Distribution -- 5.3 Lattice Distortion -- 5.4 Microstructure Evolutions -- 5.5 Other Advanced Characterization Methods -- References -- Chapter 6 Mechanical Properties -- 6.1 Introduction -- 6.2 Exceptional Toughness at Cryogenic Temperatures -- 6.3 Superior Performances at Elevated Temperatures -- 6.4 Improved Hardness: Toward Super Hard Materials -- 6.5 More Examples on HEMs with Intriguing Mechanical Properties -- 6.6 Strengthen Mechanisms -- 6.6.1 Theory on Yield Strength -- 6.6.2 Short Range Order -- 6.6.3 Grain Boundary Segregation -- 6.7 Microstructure-Mechanism-Based Design Approaches -- 6.8 Conclusions and Perspectives -- References -- Chapter 7 Functional Properties -- 7.1 Thermal Conductivity -- 7.2 Thermal Expansion -- 7.3 Oxidation Resistance -- 7.4 Molten Salt Corrosion Resistance -- 7.5 Irradiation Resistance -- 7.6 Electronic and Ionic Conductivity -- 7.7 Dielectric Properties -- 7.8 Magnetic Properties -- References -- Chapter 8 Applications of High-Entropy Materials -- 8.1 Introduction -- 8.2 Structural Applications -- 8.3 Thermal Protection and Management -- 8.4 Thermoelectricity -- 8.5 Electromagnetic Wave (EMW) Absorption -- 8.6 Rechargeable Batteries -- 8.7 Other Applications -- 8.8 Summary and Perspectives -- References.
327   $aChapter 9 Challenges and Future Directions of High-Entropy Materials -- 9.1 Introduction -- 9.2 Vastness of Tunable Elements, Microstructures, and Properties -- 9.3 Preparation, Characterization, and Modeling -- 9.4 Materials Database, Materials Screening, and Design -- 9.5 Conclusions -- References -- Index -- EULA.
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