Spark-Plasma Sintering and Related Field-Assisted Powder Consolidation Technologies

doi:10.3390/books978-3-03842-383-6

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Spark-Plasma Sintering and Related Field-Assisted Powder Consolidation Technologies

Edited by

March 2017

192 pages

ISBN978-3-03842-382-9 (Paperback)
ISBN978-3-03842-383-6 (PDF)

https://doi.org/10.3390/books978-3-03842-383-6

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This book is a reprint of the Special Issue Spark-Plasma Sintering and Related Field-Assisted Powder Consolidation Technologies that was published in

Chemistry & Materials Science

Engineering

Physical Sciences

Summary

Electromagnetic field-assisted sintering techniques have increasingly attracted attention of scientists and technologists. Spark-plasma sintering (SPS) and other field-assisted powder consolidation approaches provide remarkable capabilities to the processing of materials into configurations previously unattainable. Of particular significance is the possibility of using very fast heating rates, which, coupled with the field-assisted mass transport, stand behind the purported ability to achieve high densities during consolidation and to maintain the nanostructure of consolidated materials via these techniques. Potentially, SPS and related technologies have many significant advantages over the conventional powder processing methods, including the lower process temperature, the shorter holding time, dramatically improved properties of sintered products, low manufacturing costs, and environmental friendliness.

In this Special Issue, modern trends of field-assisted sintering, including the processing fundamentals and optimization of final product properties, are highlighted and discussed.

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Keywords

field-assisted; powder consolidation; steel; oxide dispersion strengthening; microwave sintering; microstructureevolution; metal; synchrotron radiation computed tomography; flash sintering; spark plasma sintering; densification; melting; electric field; electric conductivity; ceramics; invasion percolation; spark-plasma sintering (SPS); BaTiO₃/3Y-TZP; fracture toughness; spark plasma sintering; inter-particle; pressureless; iron aluminide; Kirkendall effect; mechanical milling; hot work tool steel; high speed steel; spark plasma sintering; grain growth; lithium; magnesium aluminate spinel; precipitation; SPS; Spark Plasma Sintering; self-propagating high-temperature synthesis; ultra-high-temperature-ceramics; carbides; mechanical properties; optical properties; creep; spinel; SPS; porous iron; hollow Fe–N powder; free pressureless spark plasma sintering; compressive strength; fracture toughness; hardness; partially stabilized zirconia (PSZ); shear strength; solid state bonding; phase transformation; spark plasma sintering (SPS); TRIP steel; yttria-stabilized tetragonal zirconia polycrystal ((3Y)-TZP); nanosilver; die-attach; current-assisted sintering; rapid joining; characterization; zirconium carbide; spark plasma sintering; finite element simulation; grain growth; thermal properties; graphene nanosheets; Al-doped-ZnO; electrical properties; spark plasma sintering; microwave sintering; flash sintering; oxide ceramics; electric conductivity; grain boundary melting; densification; Spark Plasma Sintering; porosity; TNZT; bioimplant; aluminum matrix composites; multilayer graphene; molybdenum disulfide; SPS sintering; W-6Ni-4Mn alloys; mechanical milling; spark plasma sintering; transmission electron microscopy; mechanical property; microwave sintering; metallic binder; microstructure; mechanical properties; response surface methodology; microwave; pressureless sintering; diamond tool bits; metallic matrix; HEA; high-entropy alloy; compositionally complex alloy (CCA); compositionally complex alloy; SPS; spark plasma sintering; solid lubricant; phase composition; microstructure; wear behaviour; magnetic refrigeration; relative cooling power; spark plasma sintering; metal matrix composites; spark plasma sintering; intermetallics; thermal analysis; diamond-copper; composites; coating; sintering; physical properties; spark plasma sintering; porous materials; pressureless sintering; space holders; reactive sintering; inter-particle contacts; spark plasma sintering; complex shapes; energy efficient; multiple parts; multiphysics simulation; deformed interface method; B-site ordering; microwave ceramics; spark plasma sintering; domains; sub-micron sized grains; quality factor; tungsten carbide-cobalt; cemented carbide; powder processing; spark plasma sintering; nanomaterials; wear; elevated temperature; co-doped ceria; flash sintering; precipitation