Defect structure and properties of nanomaterials

Defect structure and properties of nanomaterials

Defect Structure and Properties of Nanomaterials: Second and Extended Edition covers a wide range of nanomaterials including metals, alloys, ceramics, diamond, carbon nanotubes, and their composites. This new edition is fully revised and updated, covering important advances that have taken place in...

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Detalles Bibliográficos
Otros Autores: Gubicza, Jenö, author (author)
Formato: Libro electrónico
Idioma:Inglés
Publicado: Duxford, England : Woodhead Publishing 2017.
Edición:Second and extended edition
Materias:
Nanostructured materials.
Ver en Biblioteca Universitat Ramon Llull:https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009630342906719
Tabla de Contenidos:
  • Front Cover
  • DEFECT STRUCTURE AND PROPERTIES OF NANOMATERIALS
  • Related titles
  • DEFECT STRUCTURE AND PROPERTIES OF NANOMATERIALS
  • Copyright
  • CONTENTS
  • LIST OF FIGURES
  • LIST OF TABLES
  • PREFACE
  • 1 - Processing Methods of Nanomaterials
  • 1.1 PROCESSING OF BULK NANOMATERIALS BY SEVERE PLASTIC DEFORMATION
  • 1.2 PRODUCTION OF NANOPOWDERS AND NANOPARTICLES
  • 1.3 CONSOLIDATION TECHNIQUES OF NANOPOWDERS
  • 1.4 PRODUCTION OF THIN FILMS BY ELECTRODEPOSITION
  • 1.5 NANOCRYSTALLIZATION OF BULK AMORPHOUS ALLOYS
  • REFERENCES
  • 2 - Characterization Methods of Lattice Defects
  • 2.1 COMPARISON OF EXPERIMENTAL METHODS USED IN THE CHARACTERIZATION OF LATTICE DEFECTS
  • 2.2 X-RAY LINE PROFILE ANALYSIS
  • 2.3 ELECTRON BACKSCATTER DIFFRACTION
  • 2.4 TRANSMISSION ELECTRON MICROSCOPY
  • 2.5 ELECTRICAL RESISTIVITY MEASUREMENT
  • 2.6 POSITRON ANNIHILATION SPECTROSCOPY
  • REFERENCES
  • 3 - Defect Structure in Bulk Nanomaterials Processed by Severe Plastic Deformation
  • 3.1 EVOLUTION OF DISLOCATION STRUCTURE AND GRAIN SIZE DURING SEVERE PLASTIC DEFORMATION PROCESSING
  • 3.2 COMPARISON OF DEFECT STRUCTURES FORMED BY DIFFERENT ROUTES OF BULK SEVERE PLASTIC DEFORMATION
  • 3.3 MAXIMUM DISLOCATION DENSITY AND MINIMUM GRAIN SIZE ACHIEVABLE BY SEVERE PLASTIC DEFORMATION OF BULK METALLIC MATERIALS
  • 3.4 EXCESS VACANCY CONCENTRATION DUE TO SEVERE PLASTIC DEFORMATION
  • 3.5 DEFECTS AND PHASE TRANSFORMATION IN NANOMATERIALS PROCESSED BY SEVERE PLASTIC DEFORMATION
  • REFERENCES
  • 4 - Defect Structure in Low Stacking Fault Energy Nanomaterials
  • 4.1 EFFECT OF LOW STACKING FAULT ENERGY ON CROSS-SLIP AND CLIMB OF DISLOCATIONS
  • 4.2 DEFECT STRUCTURE DEVELOPED IN SEVERE PLASTIC DEFORMATION-PROCESSED LOW STACKING FAULT ENERGY PURE AG
  • 4.3 EFFECT OF LOW STACKING FAULT ENERGY ON DEFECT STRUCTURE IN ULTRAFINE-GRAINED ALLOYS.
  • 4.4 GRAIN-REFINEMENT MECHANISMS IN LOW STACKING FAULT ENERGY ALLOYS
  • REFERENCES
  • 5 - Lattice Defects in Nanoparticles and Nanomaterials Sintered From Nanopowders
  • 5.1 DEVELOPMENT OF DEFECT STRUCTURE IN POWDERS DURING MILLING
  • 5.2 DEFECTS IN NANOPARTICLES PRODUCED BY BOTTOM-UP APPROACHES
  • 5.3 EFFECT OF CONSOLIDATION CONDITIONS ON MICROSTRUCTURE OF SINTERED METALS
  • 5.4 DEFECT STRUCTURE IN METALS SINTERED FROM BLENDS OF POWDERS WITH DIFFERENT PARTICLE SIZES
  • 5.5 EVOLUTION OF MICROSTRUCTURE DURING CONSOLIDATION OF DIAMOND AND CERAMIC NANOPOWDERS
  • REFERENCES
  • 6 - Lattice Defects in Nanocrystalline Films and Multilayers
  • 6.1 DEFECTS IN NANOCRYSTALLINE FILMS
  • 6.2 LATTICE DEFECTS IN MULTILAYERS
  • 6.3 EVOLUTION OF DEFECT STRUCTURE DURING PLASTIC DEFORMATION OF THIN FILMS
  • 6.4 INFLUENCE OF IRRADIATION ON DEFECT STRUCTURE IN MULTILAYERS
  • REFERENCES
  • 7 - Correlation Between Defect Structure and Mechanical Properties of Nanocrystalline Materials
  • 7.1 EFFECT OF GRAIN SIZE ON DEFORMATION MECHANISMS IN FCC AND HCP NANOMATERIALS
  • 7.2 BREAKDOWN OF HALL-PETCH BEHAVIOR IN NANOMATERIALS
  • 7.3 CORRELATION BETWEEN DISLOCATION STRUCTURE AND YIELD STRENGTH OF ULTRAFINE-GRAINED FCC METALS AND ALLOYS PROCESSED BY SEVERE ...
  • 7.4 DEFECT STRUCTURE AND DUCTILITY OF NANOMATERIALS
  • 7.5 INFLUENCE OF SINTERING CONDITIONS ON STRENGTH AND DUCTILITY OF CONSOLIDATED NANOMATERIALS
  • 7.6 MECHANICAL BEHAVIOR OF MATERIALS SINTERED FROM BLENDS OF POWDERS WITH DIFFERENT PARTICLE SIZES
  • 7.7 DEFECT STRUCTURE AND MECHANICAL PERFORMANCE OF NANOMATERIALS AT HIGH STRAIN RATES
  • REFERENCES
  • 8 - Defect Structure and Properties of Metal Matrix-Carbon Nanotube Composites
  • 8.1 PROCESSING OF METAL MATRIX-CARBON NANOTUBE COMPOSITES
  • 8.2 MORPHOLOGY OF CARBON NANOTUBES AND POROSITY IN NANOTUBE COMPOSITES
  • 8.3 DEFECT STRUCTURE IN METAL-NANOTUBE COMPOSITES.
  • 8.4 CORRELATION BETWEEN DEFECT STRUCTURE AND MECHANICAL PROPERTIES OF NANOTUBE-REINFORCED COMPOSITES
  • 8.5 ELECTRICAL CONDUCTIVITY OF METAL-CARBON NANOTUBE COMPOSITES
  • REFERENCES
  • 9 - Effect of Lattice Imperfections on Electrical Resistivity of Nanomaterials
  • 9.1 CONTRIBUTION OF LATTICE DEFECTS TO ELECTRICAL RESISTIVITY
  • 9.2 CHANGE OF RESISTIVITY IN NANOMATERIALS PROCESSED BY SEVERE PLASTIC DEFORMATION
  • 9.3 PROCESSING OF NANOMATERIALS WITH HIGH HARDNESS AND GOOD CONDUCTIVITY
  • 9.4 ELECTRICAL RESISTIVITY OF NANOSTRUCTURED FILMS
  • REFERENCES
  • 10 - Lattice Defects and Diffusion in Nanomaterials
  • 10.1 EFFECT OF LATTICE DEFECTS ON DIFFUSION
  • 10.2 DIFFUSION IN ULTRAFINE-GRAINED AND NANOCRYSTALLINE MATERIALS PROCESSED BY SEVERE PLASTIC DEFORMATION
  • 10.3 DIFFUSION IN NANOMATERIALS PROCESSED BY BOTTOM-UP METHODS
  • REFERENCES
  • 11 - Relationship Between Microstructure and Hydrogen Storage Properties of Nanomaterials
  • 11.1 FUNDAMENTALS OF HYDROGEN STORAGE IN SOLID STATE MATERIALS
  • 11.2 MICROSTRUCTURE AND HYDROGEN STORAGE IN NANOMATERIALS PROCESSED BY SEVERE PLASTIC DEFORMATION
  • 11.3 CHANGE OF DEFECT STRUCTURE DURING DEHYDROGENATION-HYDROGENATION CYCLES
  • 11.4 EFFECT OF DEFECTS ON HYDROGEN STORAGE PROPERTIES OF CARBON NANOTUBES
  • REFERENCES
  • 12 - Thermal Stability of Defect Structures in Nanomaterials
  • 12.1 HIGH-TEMPERATURE THERMAL STABILITY OF NANOSTRUCTURES IN METALLIC MATERIALS
  • 12.2 CONTRIBUTIONS OF THE DIFFERENT LATTICE DEFECTS TO THE ENERGY RELEASED IN CALORIMETRY
  • 12.3 COMPARISON OF THE THERMAL STABILITY OF ULTRAFINE-GRAINED CU PROCESSED BY SEVERE PLASTIC DEFORMATION AND POWDER METALLURGY
  • 12.4 EFFECT OF CARBON NANOTUBES ON THE STABILITY OF METAL MATRIX NANOSTRUCTURES
  • 12.5 INHOMOGENEOUS THERMAL STABILITY OF ULTRAFINE-GRAINED SILVER PROCESSED BY HIGH-PRESSURE TORSION.
  • 12.6 STABILITY OF NANOSTRUCTURED CU DURING STORAGE AT ROOM TEMPERATURE
  • 12.7 SELF-ANNEALING IN NANOSTRUCTURED SILVER: THE SIGNIFICANCE OF A VERY LOW STACKING FAULT ENERGY
  • 12.8 SELF-ANNEALING IN SEVERE PLASTIC DEFORMATION-PROCESSED ALLOYS WITH LOW MELTING POINT
  • 12.9 EVOLUTION OF SIZE AND SHAPE OF GOLD NANOPARTICLES DURING THEIR STORAGE AT ROOM TEMPERATURE
  • REFERENCES
  • INDEX
  • A
  • B
  • C
  • D
  • E
  • F
  • G
  • H
  • I
  • J
  • L
  • M
  • N
  • O
  • P
  • R
  • S
  • T
  • U
  • V
  • W
  • X
  • Y
  • Z
  • Back Cover.

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