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Heat resistant alloys. --- Nickel alloys. --- Alloys --- High temperature metals --- Refractory metals --- Superalloys --- Heat resistant materials --- Metallurgy.
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The present work investigates neutron-irradiated EUROFER97 by high-temperature indentation. Before, a test procedure is defined for the prototype device Karlsruhe high-temperature indenter. The procedure leads to a quality of the test results at high temperatures comparable to commercial devices at room temperature. The results contribute to a better understanding of structural materials of future fusion reactors.
Mechanical engineering & materials --- Fusion --- Strukturmaterialien --- Härte --- Neutronenschäden --- Hochtemperatur --- Hardness --- High-temperature --- structural materials --- Neutron-induced defects
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TBC materials in the hot components of a gas turbine are exposed to extremely harsh environments. Therefore, the evaluation of various environmental factors in applying new TBCs is essential. Understanding the mechanisms for degradation which occur in comprehensive environments plays an important role in preventing it and improving the lifetime performance. The development of novel coating techniques can also have a significant impact on lifetime performance as they can alter the microstructure of the coating and alter the various properties resulting from it. This Special Issue presents an original research paper that reports the development of novel TBCs, particularly the application of advanced deposition techniques and novel materials.
History of engineering & technology --- degradation --- high mechanical fatigue --- hot gas path components --- gas turbine lifetime --- gas turbine blade --- ANNs --- passive methods --- building energy --- internal covering --- thermal barrier coating (TBC) --- BaLa2Ti3O10 --- molten salt corrosion --- corrosion mechanisms --- crack healing --- encapsulation --- healing agent --- thermal barrier coating --- thermal durability --- cyclic thermal fatigue --- crack growth --- initial crack length --- failure --- hydrogenated amorphous silicon films --- high temperature oxidation --- super-low friction --- plasma spray–physical vapor deposition --- thermal stability --- thermal barrier coatings --- bond coat species --- electron beam-physical vapor deposition --- cyclic thermal exposure --- plasma spraying --- SrZrO3 --- TBC --- CMAS --- luminescence --- high temperature wear behavior --- dry sliding wear --- CoNiCrAlY --- detonation gun (D-gun) --- supersonic plasma spraying (SSPS)
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TBC materials in the hot components of a gas turbine are exposed to extremely harsh environments. Therefore, the evaluation of various environmental factors in applying new TBCs is essential. Understanding the mechanisms for degradation which occur in comprehensive environments plays an important role in preventing it and improving the lifetime performance. The development of novel coating techniques can also have a significant impact on lifetime performance as they can alter the microstructure of the coating and alter the various properties resulting from it. This Special Issue presents an original research paper that reports the development of novel TBCs, particularly the application of advanced deposition techniques and novel materials.
degradation --- high mechanical fatigue --- hot gas path components --- gas turbine lifetime --- gas turbine blade --- ANNs --- passive methods --- building energy --- internal covering --- thermal barrier coating (TBC) --- BaLa2Ti3O10 --- molten salt corrosion --- corrosion mechanisms --- crack healing --- encapsulation --- healing agent --- thermal barrier coating --- thermal durability --- cyclic thermal fatigue --- crack growth --- initial crack length --- failure --- hydrogenated amorphous silicon films --- high temperature oxidation --- super-low friction --- plasma spray–physical vapor deposition --- thermal stability --- thermal barrier coatings --- bond coat species --- electron beam-physical vapor deposition --- cyclic thermal exposure --- plasma spraying --- SrZrO3 --- TBC --- CMAS --- luminescence --- high temperature wear behavior --- dry sliding wear --- CoNiCrAlY --- detonation gun (D-gun) --- supersonic plasma spraying (SSPS)
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The characterization of the physical and chemical properties of transition metals and their compounds under extreme conditions of pressure and temperature has always attracted the interest of a wide scientific community. Their properties have numerous implications in fields ranging from solid-state physics, chemistry, and materials science to Earth and planetary science. The present Special Issue represents a good example of such a broad interest and shows some of the latest advancements in the investigation of transition metals under extreme conditions of pressure and temperature.
Technology: general issues --- vanadate --- kagome compound --- high pressure --- X-ray diffraction --- equation of state --- iodate --- infrared spectroscopy --- phase transitions --- grain refinement --- mechanical properties --- commercial purity aluminum --- zirconium --- Nb3Sn --- local atomic structure --- XAFS --- melting curves --- laser-heated diamond anvil cell --- extreme conditions --- synchrotron radiation --- transition metals --- iridium --- laser heating --- density-functional theory --- melting --- radial-distribution function --- quantum molecular dynamics --- melting curve --- solid-solid phase transition boundary --- multi-phase materials --- phase relation --- Earth's core --- iron alloys --- high-pressure --- high-temperature --- thermodynamics --- eutectic spacing --- Al-Si alloy --- superheat --- electrical resistivity --- iron sulfides --- high temperature --- Ganymede --- thermal convection --- creep testing --- ME21 --- magnesium alloy --- size effects --- miniature specimen --- PbTe --- substitutional disorder --- thermal expansion --- bulk modulus --- atomic displacement --- low temperature --- compression --- Debye temperature --- vanadate --- kagome compound --- high pressure --- X-ray diffraction --- equation of state --- iodate --- infrared spectroscopy --- phase transitions --- grain refinement --- mechanical properties --- commercial purity aluminum --- zirconium --- Nb3Sn --- local atomic structure --- XAFS --- melting curves --- laser-heated diamond anvil cell --- extreme conditions --- synchrotron radiation --- transition metals --- iridium --- laser heating --- density-functional theory --- melting --- radial-distribution function --- quantum molecular dynamics --- melting curve --- solid-solid phase transition boundary --- multi-phase materials --- phase relation --- Earth's core --- iron alloys --- high-pressure --- high-temperature --- thermodynamics --- eutectic spacing --- Al-Si alloy --- superheat --- electrical resistivity --- iron sulfides --- high temperature --- Ganymede --- thermal convection --- creep testing --- ME21 --- magnesium alloy --- size effects --- miniature specimen --- PbTe --- substitutional disorder --- thermal expansion --- bulk modulus --- atomic displacement --- low temperature --- compression --- Debye temperature
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TBC materials in the hot components of a gas turbine are exposed to extremely harsh environments. Therefore, the evaluation of various environmental factors in applying new TBCs is essential. Understanding the mechanisms for degradation which occur in comprehensive environments plays an important role in preventing it and improving the lifetime performance. The development of novel coating techniques can also have a significant impact on lifetime performance as they can alter the microstructure of the coating and alter the various properties resulting from it. This Special Issue presents an original research paper that reports the development of novel TBCs, particularly the application of advanced deposition techniques and novel materials.
History of engineering & technology --- degradation --- high mechanical fatigue --- hot gas path components --- gas turbine lifetime --- gas turbine blade --- ANNs --- passive methods --- building energy --- internal covering --- thermal barrier coating (TBC) --- BaLa2Ti3O10 --- molten salt corrosion --- corrosion mechanisms --- crack healing --- encapsulation --- healing agent --- thermal barrier coating --- thermal durability --- cyclic thermal fatigue --- crack growth --- initial crack length --- failure --- hydrogenated amorphous silicon films --- high temperature oxidation --- super-low friction --- plasma spray–physical vapor deposition --- thermal stability --- thermal barrier coatings --- bond coat species --- electron beam-physical vapor deposition --- cyclic thermal exposure --- plasma spraying --- SrZrO3 --- TBC --- CMAS --- luminescence --- high temperature wear behavior --- dry sliding wear --- CoNiCrAlY --- detonation gun (D-gun) --- supersonic plasma spraying (SSPS) --- degradation --- high mechanical fatigue --- hot gas path components --- gas turbine lifetime --- gas turbine blade --- ANNs --- passive methods --- building energy --- internal covering --- thermal barrier coating (TBC) --- BaLa2Ti3O10 --- molten salt corrosion --- corrosion mechanisms --- crack healing --- encapsulation --- healing agent --- thermal barrier coating --- thermal durability --- cyclic thermal fatigue --- crack growth --- initial crack length --- failure --- hydrogenated amorphous silicon films --- high temperature oxidation --- super-low friction --- plasma spray–physical vapor deposition --- thermal stability --- thermal barrier coatings --- bond coat species --- electron beam-physical vapor deposition --- cyclic thermal exposure --- plasma spraying --- SrZrO3 --- TBC --- CMAS --- luminescence --- high temperature wear behavior --- dry sliding wear --- CoNiCrAlY --- detonation gun (D-gun) --- supersonic plasma spraying (SSPS)
Choose an application
The characterization of the physical and chemical properties of transition metals and their compounds under extreme conditions of pressure and temperature has always attracted the interest of a wide scientific community. Their properties have numerous implications in fields ranging from solid-state physics, chemistry, and materials science to Earth and planetary science. The present Special Issue represents a good example of such a broad interest and shows some of the latest advancements in the investigation of transition metals under extreme conditions of pressure and temperature.
Technology: general issues --- vanadate --- kagome compound --- high pressure --- X-ray diffraction --- equation of state --- iodate --- infrared spectroscopy --- phase transitions --- grain refinement --- mechanical properties --- commercial purity aluminum --- zirconium --- Nb3Sn --- local atomic structure --- XAFS --- melting curves --- laser-heated diamond anvil cell --- extreme conditions --- synchrotron radiation --- transition metals --- iridium --- laser heating --- density-functional theory --- melting --- radial-distribution function --- quantum molecular dynamics --- melting curve --- solid–solid phase transition boundary --- multi-phase materials --- phase relation --- Earth’s core --- iron alloys --- high-pressure --- high-temperature --- thermodynamics --- eutectic spacing --- Al-Si alloy --- superheat --- electrical resistivity --- iron sulfides --- high temperature --- Ganymede --- thermal convection --- creep testing --- ME21 --- magnesium alloy --- size effects --- miniature specimen --- PbTe --- substitutional disorder --- thermal expansion --- bulk modulus --- atomic displacement --- low temperature --- compression --- Debye temperature --- n/a --- solid-solid phase transition boundary --- Earth's core
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This book is an exciting collection of research articles that offer a unique view into the fast developing field of metal additive manufacturing, providing insights into this advanced manufacturing technology. The articles span recent advances in metal AM technologies, and their application to a wide range of metals, exploring how the processing parameters offer unique material properties. This book encapsulates the state of the art in this rapidly evolving field of technology and will be a valuable resource for researchers in the field, from Ph.D. students to professors, and through to industrial end users.
Technology: general issues --- additive manufacturing --- laser powder bed fusion --- A357.0 --- mechanical performance --- Laser powder bed fusion --- selective laser melting --- SKD61 tool steel --- nanoindentation --- strain-rate sensitivity --- nonhorizontal suspension structure --- boundary remelting --- surface roughness --- forming accuracy --- Ti–6Al–4V alloy --- metallurgical quality --- mechanical properties --- aluminum alloys --- high-temperature deformation --- microstructure --- selective laser melting (SLM) --- Ti alloy --- high temperature tensile --- erosion --- wear --- construction --- WAAM --- welding --- steel --- ESPI --- design --- powder bed fusion (PBF) --- Ti-6Al-4V --- phase transformation --- tensile --- 90W-7Ni-3Fe --- densification --- properties --- hyper-duplex stainless steel --- mechanical property --- corrosion resistance --- Alsi10Mg --- stress relieve --- Inconel 718 --- embrittlement --- titanium --- drilling --- chip geometry --- cutting forces --- hole quality --- DED --- laser --- thermal conductivity --- thermal diffusivity --- thermal modeling --- hot stamping --- AISI H13 --- plasma transferred arc --- processing conditions --- Hastelloy C-22 --- wire and arc additive manufacturing --- low-carbon high-strength steel --- anisotropy
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The characterization of the physical and chemical properties of transition metals and their compounds under extreme conditions of pressure and temperature has always attracted the interest of a wide scientific community. Their properties have numerous implications in fields ranging from solid-state physics, chemistry, and materials science to Earth and planetary science. The present Special Issue represents a good example of such a broad interest and shows some of the latest advancements in the investigation of transition metals under extreme conditions of pressure and temperature.
vanadate --- kagome compound --- high pressure --- X-ray diffraction --- equation of state --- iodate --- infrared spectroscopy --- phase transitions --- grain refinement --- mechanical properties --- commercial purity aluminum --- zirconium --- Nb3Sn --- local atomic structure --- XAFS --- melting curves --- laser-heated diamond anvil cell --- extreme conditions --- synchrotron radiation --- transition metals --- iridium --- laser heating --- density-functional theory --- melting --- radial-distribution function --- quantum molecular dynamics --- melting curve --- solid–solid phase transition boundary --- multi-phase materials --- phase relation --- Earth’s core --- iron alloys --- high-pressure --- high-temperature --- thermodynamics --- eutectic spacing --- Al-Si alloy --- superheat --- electrical resistivity --- iron sulfides --- high temperature --- Ganymede --- thermal convection --- creep testing --- ME21 --- magnesium alloy --- size effects --- miniature specimen --- PbTe --- substitutional disorder --- thermal expansion --- bulk modulus --- atomic displacement --- low temperature --- compression --- Debye temperature --- n/a --- solid-solid phase transition boundary --- Earth's core
Listing 1 - 10 of 75 | << page >> |
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