Metallic glasses and their composites /

Metallic glasses and their composites /

The formation of metallic glasses and dual-phase composite/hybrid materials is reviewed, as well as the glass transition process and the resulting structural phenomena. These materials exhibit high strength, extreme hardness, good wear resistance and large elastic deformation

Bibliographic Details
Main Author: Louzguine-Luzgin, Dmitri V. (Author)
Format: Book
Language:English
Published: Millersville, PA : Materials Research Forum, [2018]
Series:Materials research foundations ; v. 19
Subjects:
Metallic glasses
Verres métalliques
TECHNOLOGY & ENGINEERING > Engineering (General)
TECHNOLOGY & ENGINEERING > Reference
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245 1 0 |a Metallic glasses and their composites /  |c D.V. Louzguine 
264 1 |a Millersville, PA :  |b Materials Research Forum,  |c [2018] 
264 4 |c ©2018 
300 |a 1 online resource (336 pages) 
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490 1 |a Materials research foundations,  |x 2471-8890 ;  |v volume 19 
504 |a Includes bibliographical references and index 
505 0 |a Front_Matter; Table of Contents; 1; 1.1 Formation of metallic glasses; 1.2 General physical properties; References; 2; 2.1 Crystal nucleation controlled mechanism; 2.2 Crystal growth controlled mechanism; 2.3 Extrinsic factors influencing glass-forming ability; 2.4 Effect of flux treatment; References; 3; 3.1 Structure of liquids and glasses; 3.2 Thermal expansion detected by X-ray diffraction; 3.3 Structural changes on glass formation from the liquid state; 3.4 Structural changes on mechanical loading; 3.5 Pressure effects, polyamorphism; References; 4 
505 8 |a 4.1 Structural relaxation and rejuvenation4.2 Phase separation; 4.2.1 Phase separation on cooling liquids; 4.2.2 Phase separation on heating metallic glasses; 4.3 Dissolution of a metastable crystalline phase in a supercooled liquid; 4.4 Crystallization of glassy alloys.; 4.4.1 General features.; 4.4.2 Nanocrystallization.; 4.4.3 Crystallization of metallic glasses above and below Tg; 4.4.4 Formation of in-situ glassy-nanocomposites upon rapid solidification; 4.4.5 Crystallization upon deformation; 4.4.6 Formation of quasicrystals upon devitrification 
505 8 |a 4.4.7 Formation of nanoscale quasicrystals4.4.8 Crystallization of the amorphous alloys containing pre-existing nuclei and nanoparticles; 4.5 Peritectic like reactions involving glassy phase; References; 5; 5.1 Mechanical properties of bulk metallic glasses and their deformation behavior at room temperature; 5.1.1 Elastic properties; 5.1.2 Mechanical strength, hardness and plasticity; 5.1.3 Plastic deformation mechanism; 5.1.4 Structural rejuvenation by deformation; 5.1.5 Strain-rate sensitivity; 5.1.6 Size effect and in-situ deformation studies 
505 8 |a 5.1.7 Fatigue, cyclic and long-term creep deformation in the elastic region. 5.1.8 Fracture toughness; 5.1.9 Fracture mechanisms; 5.1.10 Dynamic mechanical properties; 5.1.11 Wear resistance; 5.1.11.1 Macroscopic wear properties; 5.1.11.2 Nano-scale and atomic-scale wear resistance; 5.1.12 Bauschinger-type effect; 5.2 Plastic flow of bulk metallic glasses on heating; 5.3 Deformation of bulk metallic glasses at cryogenic temperature; 5.4 Non-uniform materials with glassy phase; 5.4.1 Porous glasses; 5.4.2 Glassy-crystalline dual phase alloys 
505 8 |a 5.4.3 Mechanical properties of nanocomposite alloysReferences; 6; 6.1 Soft magnetic alloys; 6.2 Hard magnetic alloys; 6.3 The magnetocaloric effect; References; 7; 7.1 Structural and functional materials; 7.2 Magnetic applications; 7.2.1 Soft magnetic applications; 7.2.2 Hard magnetic applications; 7.3 Corrosion resistant alloys; 7.4 Surface oxides for electronic devices; 7.5 Cleaning water pollutions; 7.6 Materials for medicine; 7.7 Catalysts; 7.8 Final remarks and future prospects; References; keyword Index 
520 |a The formation of metallic glasses and dual-phase composite/hybrid materials is reviewed, as well as the glass transition process and the resulting structural phenomena. These materials exhibit high strength, extreme hardness, good wear resistance and large elastic deformation 
588 0 |a Online resource; title from PDF title page (EBSCO, viewed January 25, 2018) 
650 0 |a Metallic glasses 
650 6 |a Verres métalliques 
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830 0 |a Materials research foundations ;  |v v. 19 
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