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|a Louzguine-Luzgin, Dmitri V.,
|e author
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|a Metallic glasses and their composites /
|c D.V. Louzguine
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|a Millersville, PA :
|b Materials Research Forum,
|c [2018]
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|c ©2018
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|a 1 online resource (336 pages)
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|a text
|b txt
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|a computer
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|a online resource
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|a Materials research foundations,
|x 2471-8890 ;
|v volume 19
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|a Includes bibliographical references and index
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|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
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|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
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|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
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|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
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|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
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|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
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|a Online resource; title from PDF title page (EBSCO, viewed January 25, 2018)
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|a Metallic glasses
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|a Verres métalliques
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|a Metallic glasses
|2 fast
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|a TECHNOLOGY & ENGINEERING
|x Engineering (General)
|2 bisacsh
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|a TECHNOLOGY & ENGINEERING
|x Reference
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|i Print version:
|a Louzguine, D.V
|t Metallic Glasses and Their Composites.
|d Millersville, PA : Materials Research Forum LLC, ©2018
|z 9781945291425
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|a Materials research foundations ;
|v v. 19
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|i 213d4c7a-c6ac-42e7-9deb-959c3005da6f
|l 13083257
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|m metallic_glasses_and_their_composites______________________________________2018_______matera________________________________________louzguine_luzgin__dm_______________e
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