Listing 1 - 10 of 15 | << page >> |
Sort by
|
Choose an application
Fatigue tests. --- Fretting. --- Porosity. --- Titanium aluminides. --- Wear tests.
Choose an application
Ternary alloys. --- Heat resistant alloys. --- Nickel aluminides. --- Intermetallics. --- Solubility.
Choose an application
Intermetallics. --- Aluminum nitrides. --- Nickel aluminides. --- Milling (machining) --- Mechanical properties. --- Roasting. --- Oxide dispersion strengthening. --- Compressive strength.
Choose an application
Space vehicles --- Thermal stresses. --- Thermal expansion. --- Sprayed coatings. --- Vacuum. --- Plasma dynamics. --- Copper alloys. --- Nickel aluminides. --- Plasmas (physics) --- Residual stress. --- Coatings.
Choose an application
Powder metallurgy is a group of advanced processes used for the synthesis, processing, and shaping of various kinds of materials. Initially inspired by ceramics processing, the methodology comprising the production of a powder and its transformation to a compact solid product has attracted attention since the end of World War II. At present, many technologies are availabe for powder production (e.g., gas atomization of the melt, chemical reduction, milling, and mechanical alloying) and its consolidation (e.g., pressing and sintering, hot isostatic pressing, and spark plasma sintering). The most promising methods can achieve an ultra-fine or nano-grained powder structure, and preserve it during consolidation. Among these methods, mechanical alloying and spark plasma sintering play a key role. This book places special focus on advances in mechanical alloying, spark plasma sintering, and self-propagating high-temperature synthesis methods, as well as on the role of these processes in the development of new materials.
History of engineering & technology --- in situ diffraction --- aluminides --- reactive sintering --- mechanism --- powder metallurgy --- iron silicide --- Fe–Al–Si alloy --- mechanical alloying --- spark plasma sintering --- characterization --- FeAlSi --- intermetallic alloys --- microstructure --- nanoindentation --- mechanical properties --- titanium aluminides and silicides --- casting --- heterophase magnesium matrix composite --- Mg2Si --- carbon nanotubes --- nanopowders de-agglomeration --- sintering --- biomaterials --- metallic composites --- powder technology --- zinc --- Ni-Ti alloy --- self-propagating high-temperature synthesis --- aging --- compressive test --- hardness --- shape memory --- maraging steel --- atomized powder --- selective laser melting --- heat treatment --- precipitation hardening --- self-healing --- aluminium alloy --- grain boundary diffusion --- Nd–Fe–B magnets --- hydrogenation --- magnetic properties --- MgAl2O4 --- lithium fluoride --- cobalt fluoride --- manganese fluoride --- grain growth --- compressive strength --- oxidation resistance --- wear --- multi principal element alloy --- tensile strength --- fracture --- ductility --- powder --- critical raw materials --- cutting tools --- new materials --- new machining methods --- modelling and simulation --- in situ diffraction --- aluminides --- reactive sintering --- mechanism --- powder metallurgy --- iron silicide --- Fe–Al–Si alloy --- mechanical alloying --- spark plasma sintering --- characterization --- FeAlSi --- intermetallic alloys --- microstructure --- nanoindentation --- mechanical properties --- titanium aluminides and silicides --- casting --- heterophase magnesium matrix composite --- Mg2Si --- carbon nanotubes --- nanopowders de-agglomeration --- sintering --- biomaterials --- metallic composites --- powder technology --- zinc --- Ni-Ti alloy --- self-propagating high-temperature synthesis --- aging --- compressive test --- hardness --- shape memory --- maraging steel --- atomized powder --- selective laser melting --- heat treatment --- precipitation hardening --- self-healing --- aluminium alloy --- grain boundary diffusion --- Nd–Fe–B magnets --- hydrogenation --- magnetic properties --- MgAl2O4 --- lithium fluoride --- cobalt fluoride --- manganese fluoride --- grain growth --- compressive strength --- oxidation resistance --- wear --- multi principal element alloy --- tensile strength --- fracture --- ductility --- powder --- critical raw materials --- cutting tools --- new materials --- new machining methods --- modelling and simulation
Choose an application
Powder metallurgy is a group of advanced processes used for the synthesis, processing, and shaping of various kinds of materials. Initially inspired by ceramics processing, the methodology comprising the production of a powder and its transformation to a compact solid product has attracted attention since the end of World War II. At present, many technologies are availabe for powder production (e.g., gas atomization of the melt, chemical reduction, milling, and mechanical alloying) and its consolidation (e.g., pressing and sintering, hot isostatic pressing, and spark plasma sintering). The most promising methods can achieve an ultra-fine or nano-grained powder structure, and preserve it during consolidation. Among these methods, mechanical alloying and spark plasma sintering play a key role. This book places special focus on advances in mechanical alloying, spark plasma sintering, and self-propagating high-temperature synthesis methods, as well as on the role of these processes in the development of new materials.
History of engineering & technology --- in situ diffraction --- aluminides --- reactive sintering --- mechanism --- powder metallurgy --- iron silicide --- Fe–Al–Si alloy --- mechanical alloying --- spark plasma sintering --- characterization --- FeAlSi --- intermetallic alloys --- microstructure --- nanoindentation --- mechanical properties --- titanium aluminides and silicides --- casting --- heterophase magnesium matrix composite --- Mg2Si --- carbon nanotubes --- nanopowders de-agglomeration --- sintering --- biomaterials --- metallic composites --- powder technology --- zinc --- Ni-Ti alloy --- self-propagating high-temperature synthesis --- aging --- compressive test --- hardness --- shape memory --- maraging steel --- atomized powder --- selective laser melting --- heat treatment --- precipitation hardening --- self-healing --- aluminium alloy --- grain boundary diffusion --- Nd–Fe–B magnets --- hydrogenation --- magnetic properties --- MgAl2O4 --- lithium fluoride --- cobalt fluoride --- manganese fluoride --- grain growth --- compressive strength --- oxidation resistance --- wear --- multi principal element alloy --- tensile strength --- fracture --- ductility --- powder --- critical raw materials --- cutting tools --- new materials --- new machining methods --- modelling and simulation
Choose an application
Powder metallurgy is a group of advanced processes used for the synthesis, processing, and shaping of various kinds of materials. Initially inspired by ceramics processing, the methodology comprising the production of a powder and its transformation to a compact solid product has attracted attention since the end of World War II. At present, many technologies are availabe for powder production (e.g., gas atomization of the melt, chemical reduction, milling, and mechanical alloying) and its consolidation (e.g., pressing and sintering, hot isostatic pressing, and spark plasma sintering). The most promising methods can achieve an ultra-fine or nano-grained powder structure, and preserve it during consolidation. Among these methods, mechanical alloying and spark plasma sintering play a key role. This book places special focus on advances in mechanical alloying, spark plasma sintering, and self-propagating high-temperature synthesis methods, as well as on the role of these processes in the development of new materials.
in situ diffraction --- aluminides --- reactive sintering --- mechanism --- powder metallurgy --- iron silicide --- Fe–Al–Si alloy --- mechanical alloying --- spark plasma sintering --- characterization --- FeAlSi --- intermetallic alloys --- microstructure --- nanoindentation --- mechanical properties --- titanium aluminides and silicides --- casting --- heterophase magnesium matrix composite --- Mg2Si --- carbon nanotubes --- nanopowders de-agglomeration --- sintering --- biomaterials --- metallic composites --- powder technology --- zinc --- Ni-Ti alloy --- self-propagating high-temperature synthesis --- aging --- compressive test --- hardness --- shape memory --- maraging steel --- atomized powder --- selective laser melting --- heat treatment --- precipitation hardening --- self-healing --- aluminium alloy --- grain boundary diffusion --- Nd–Fe–B magnets --- hydrogenation --- magnetic properties --- MgAl2O4 --- lithium fluoride --- cobalt fluoride --- manganese fluoride --- grain growth --- compressive strength --- oxidation resistance --- wear --- multi principal element alloy --- tensile strength --- fracture --- ductility --- powder --- critical raw materials --- cutting tools --- new materials --- new machining methods --- modelling and simulation
Choose an application
The dynamic development of global industry and growing demand for new material technologies generate constantly increasing problems regarding premature material degradation and the requirement to determine corrosion mechanisms and to develop new protection/evaluation approaches. Corrosion resistance depends on numerous determinants, such as material structure, chemistry, and complex environmental factors. It is highly challenging to obtain consensus between high corrosion resistance and an economic approach. On the other hand, inadequate levels of corrosion control create serious hazards to life and the environment. This Special Issue, “Recent Advances in Corrosion Science”, brings together fourteen articles and one review, providing a snapshot of the recent activity and development in this field. The book contains studies related to the development of new corrosion-resistant alloys and the determination of microstructure-dependent properties; it also provides an insight into recent approaches towards anticorrosion technologies, such as corrosion inhibitors and composite and metal protective coatings.
Research & information: general --- corrosion inhibitor --- electrochemical --- AFM --- CO2 corrosion --- austempered gray cast iron --- austempering temperature --- microstructure --- potentiodynamic polarization --- electrochemical impedance spectroscopy --- titanium-based alloys --- passivity breakdown --- pitting corrosion --- carbon steel --- indazole derivatives --- electrochemistry --- DFT --- thermal diffusion coatings --- grade 10.9 bolts --- corrosion resistance --- thermal deformation parameters --- 35CrMoV steel --- grain size --- electrochemical corrosion --- aluminum alloys --- phase characterization --- de-alloying --- titanium aluminides --- oxidation --- non-isothermal --- mechanism --- internal oxidation --- pre-corrosion pits --- residual fatigue life --- 42CrMo steel --- stress intensity factor --- aluminum alloy --- alkaline environment --- impedance analysis --- adsorption --- dihydroxybenzene --- magnesium --- immersion test --- polarization --- cleaning --- bond coat --- PDC coatings --- fillers --- EC-AFM --- corrosion --- metallic materials --- metal coatings --- nickel --- composite coatings --- electrodeposition --- XPS --- electrochemical impedance spectroscopy (EIS) --- boron-doped diamond --- high-temperature treatment --- surface oxidation --- microstructure defects --- electrochemical activity --- corrosion inhibitor --- electrochemical --- AFM --- CO2 corrosion --- austempered gray cast iron --- austempering temperature --- microstructure --- potentiodynamic polarization --- electrochemical impedance spectroscopy --- titanium-based alloys --- passivity breakdown --- pitting corrosion --- carbon steel --- indazole derivatives --- electrochemistry --- DFT --- thermal diffusion coatings --- grade 10.9 bolts --- corrosion resistance --- thermal deformation parameters --- 35CrMoV steel --- grain size --- electrochemical corrosion --- aluminum alloys --- phase characterization --- de-alloying --- titanium aluminides --- oxidation --- non-isothermal --- mechanism --- internal oxidation --- pre-corrosion pits --- residual fatigue life --- 42CrMo steel --- stress intensity factor --- aluminum alloy --- alkaline environment --- impedance analysis --- adsorption --- dihydroxybenzene --- magnesium --- immersion test --- polarization --- cleaning --- bond coat --- PDC coatings --- fillers --- EC-AFM --- corrosion --- metallic materials --- metal coatings --- nickel --- composite coatings --- electrodeposition --- XPS --- electrochemical impedance spectroscopy (EIS) --- boron-doped diamond --- high-temperature treatment --- surface oxidation --- microstructure defects --- electrochemical activity
Choose an application
By the late 1940s, and since then, the continuous development of dislocation theories have provided the basis for correlating the macroscopic time-dependent deformation of metals and alloys—known as creep—to the time-dependent processes taking place within the metals and alloys. High-temperature deformation and stress relaxation effects have also been explained and modeled on similar bases. The knowledge of high-temperature deformation as well as its modeling in conventional or unconventional situations is becoming clearer year by year, with new contemporary and better performing high-temperature materials being constantly produced and investigated.This book includes recent contributions covering relevant topics and materials in the field in an innovative way. In the first section, contributions are related to the general description of creep deformation, damage, and ductility, while in the second section, innovative testing techniques of creep deformation are presented. The third section deals with creep in the presence of complex loading/temperature changes and environmental effects, while the last section focuses on material microstructure–creep correlations for specific material classes. The quality and potential of specific materials and microstructures, testing conditions, and modeling as addressed by specific contributions will surely inspire scientists and technicians in their own innovative approaches and studies on creep and high-temperature deformation.
Larson–Miller parameter --- n/a --- visualization --- bond coat --- hydrogen --- poly-crystal --- Gibbs free energy principle --- constitutive equations --- creep damage --- DFT --- finite element method --- austenitic stainless steel --- strain rate sensitivity --- MCrAlY --- excess volume --- superalloy --- scanning electron microscopy --- creep buckling --- dislocation dynamics --- creep --- elevated temperature --- modelling --- size effect --- residual stress --- superalloy VAT 32 --- water vapor --- activation energy --- small angle neutron scattering --- superalloy VAT 36 --- metallic glass --- iron aluminides --- Gr.91 --- internal stress --- relaxation fatigue --- multiaxiality --- creep grain boundary --- grain boundary cavitation --- cavitation --- solute atom --- stress exponent --- external pressure --- P92 --- TMA --- low cycle fatigue --- nanoindentation --- high temperature --- FEM --- intrinsic ductility --- normalizing --- creep ductility --- creep rupture mechanism --- microstructural features --- simulate HAZ --- P92 steel --- glide --- ferritic–martensitic steel --- creep rupture --- cyclic softening
Choose an application
There is growing interest in light metallic alloys for a wide number of applications owing to their processing efficiency, processability, long service life, and environmental sustainability. Aluminum, magnesium, and titanium alloys are addressed in this Special Issue, however, the predominant role played by aluminum. The collection of papers published here covers a wide range of topics that generally characterize the performance of the alloys after manufacturing by conventional and innovative processing routes.
fatigue properties --- hydroforming --- AlSi12Cu1(Fe) --- magnesium alloy --- microstructure --- Ti6Al4V titanium alloy --- FEM simulation --- aging treatment --- AlSi11Cu2(Fe) --- titanium aluminides --- commercially pure titanium --- hot working --- quenching process --- hot rolling --- 7003 alloy --- compressive strength --- plastic strain --- precipitation --- constitutive equations --- processing temperature --- material property --- hot forging --- wear resistance --- hot deformation behavior --- solid solution hardening --- microstructural changes --- fatigue behavior --- hardening criteria --- AlSi10Mg alloy --- 7XXX Al alloy --- hot compression --- creep --- Al-5Mg wire electrode --- ultra-fine grain --- mechanical properties --- cooling rate --- residual stress --- thermomechanical treatment --- remanufacturing --- hot workability --- activation energy --- mechanical alloying --- selective laser melting --- alloy --- Al alloy --- dynamic recrystallization --- springback --- wire feedability --- cold rolling --- spray deposited --- rotary-die equal-channel angular pressing --- adhesion strength --- microarc oxidation --- aluminum alloy --- Zr --- processing map --- Al–Si alloy --- UNS A92024-T3 --- Al-Si-Cu alloys --- sludge --- high pressure die casting --- fractography --- 2024-T4 aluminum alloys --- anode pulse-width --- consolidation --- high temperature --- AlSi9Cu3(Fe) --- FEP --- resistance spot welding --- intermetallics --- tensile properties --- tensile property --- iron
Listing 1 - 10 of 15 | << page >> |
Sort by
|