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Advances in science and technology of Mn+1AXn phases /

Advances in Science and Technology of Mn+1AXn Phases presents a comprehensive review of synthesis, microstructures, properties, ab-initio calculations and applications of Mn+1AXn phases and targets the continuing research of advanced materials and ceramics. An overview of the current status, future...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Low, I. M.
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Philadelphia : Woodhead Pub., 2012.
Colección:Woodhead publishing in mechanical engineering
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Advances in science andtechnology of M n+1 AX nphases; Copyright; Contents; Figures; Tables; Preface; Recommended Reading; About the editor and contributors; 1 Methods of MAX-phase synthesis and densification
  • I; 1.1 Introduction; 1.2 Synthesis methods; References; 2 Methods of MAX-phase synthesis and densification
  • II; 2.1 Introduction; 2.2 Powder synthesis; 2.3 Synthesis of solids; 2.4 Synthesis of thin films; 2.5 Mechanisms of reaction synthesis for MAX phases; 2.6 Conclusions; References; 3 Consolidation and synthesis of MAX phases by Spark Plasma Sintering (SPS): a review.
  • 3.1 Introduction3.2 Spark plasma sintering; 3.3 Spark plasma sintering of MAX phases; 3.4 MAX phase composites; 3.5 MAX phase solid solutions; 3.6 MAX phase coatings; 3.7 Conclusions; References; Microstructural examination during the formation of Ti3AlC2 from mixtures of Ti/Al/C and Ti/Al/TiC; 4.1 Introduction; 4.2 Experimental procedure; 4.3 Effect of starting powder mixtures on formation of Ti3AlC2; 4.4 Reaction routes for powder mixture of 3Ti/Al/2C; 4.5 Reaction routes for powder mixture of Ti/Al/2TiC; 4.6 Summary; References.
  • 5 Fabrication of in situ Ti2AlN/TiAl composites and their mechanical, friction and wear properties5.1 Introduction; 5.2 Fabrication of Ti2AlN/TiAl composites; 5.3 Mechanical properties of Ti2AlN/TiAl composites; 5.4 Friction and wear properties of Ti2AlN/TiAl composites at room temperature; 5.5 Friction and wear properties of Ti2AlN/TiAl composites at high temperature; 5.6 Conclusions; References; 6 Use of MAX particles to improve the toughness of brittle ceramics; 6.1 Introduction; 6.2 Experimental; 6.3 Results and discussion; 6.4 Conclusions; References.
  • 7 Electrical properties of MAX phases7.1 Introduction; 7.2 Resistivity; 7.3 Conduction mechanisms; 7.4 Superconductivity; 7.5 Conclusions; Acknowledgement; References; 8 Theoretical study of physicalproperties and oxygen incorporationeffect in nanolaminated ternarycarbides 211-MAX phases; 8.1 Introduction; 8.2 Crystal structure of MAX phases; 8.3 Steric effect on the M-site in MAX phases; 8.4 Bulk modulus of MAX phases; 8.5 Analysis of the electronic structure; 8.6 Elastic properties; 8.7 Effect of oxygen incorporation on the structural, elastic and electronic properties in Ti2SnC.
  • 8.8 ConclusionsNote; References; 9 Computational modelling and ab initio calculations in MAX phases
  • I; 9.1 Introduction; 9.2 Density functional theory; 9.3 The structural properties of M n+1AX n under pressure; 9.4 Ab initio study of electronicproperties; 9.5 Ab initio study of mechanicalproperties; 9.6 Ab initio study of optical properties; References; 10 Computational modeling and ab initiocalculations in MAX phases
  • II; 10.1 Computational modeling of MAX phases; 10.2 Electronic structures and properties of MAX phases; 10.3 Stabilities and occurrences of MAX phases.