English
Deutsch
Español
Français
Hrvatski
Italiano
Polski
Türkçe
Русский
中文
日本語
한국어
Legal notice
powered by CADENAS

Top Links

Social Share

ALL#ABCDEFGHIJKLMNOPQRSTUVWXYZ

Scandium hydride (7840 views - Material Database)

Scandium hydride, also known as scandium–hydrogen alloy, is an alloy made by combining scandium and hydrogen. Hydrogen acts as a hardening agent, preventing dislocations in the scandium atom crystal lattice from sliding past one another. Varying the amount of hydrogen controls qualities such as the hardness of the resulting scandium hydride. Scandium hydride with increased hydrogen content can be made harder than scandium. It can be formed by progressive hydrogenation of scandium foil with hydrogen. In the narrow range of concentrations which make up scandium hydride, mixtures of hydrogen and scandium can form two different structures. At room temperature, the most stable form of scandium is the hexagonal close-packed (HCP) structure α-scandium. It is a fairly soft metallic material that can dissolve a moderate concentration of hydrogen, no more than 0.89 wt% at 22 °C. If scandium hydride contains more than 0.89% hydrogen at room temperature then it transforms into a face-centred cubic (FCC) structure, the δ-phase. It can dissolve considerably more hydrogen, as much as 4.29%, which reflects the upper hydrogen content of scandium hydride. Research indicates the existence of a third phase created under extreme conditions termed the η-phase. This phase can dissolve as much as 6.30% hydrogen. Concentration dependent activation-energies are observed for hydrogen diffusion in scandium metal.
Go to Article

Scandium hydride

Scandium hydride

This article is about the scandium–hydrogen alloy. For the chemical compound, see Scandium(III) hydride.

Scandium hydride, also known as scandium–hydrogen alloy, is an alloy made by combining scandium and hydrogen. Hydrogen acts as a hardening agent, preventing dislocations in the scandium atom crystal lattice from sliding past one another. Varying the amount of hydrogen controls qualities such as the hardness of the resulting scandium hydride. Scandium hydride with increased hydrogen content can be made harder than scandium.

It can be formed by progressive hydrogenation of scandium foil with hydrogen.[1]

In the narrow range of concentrations which make up scandium hydride, mixtures of hydrogen and scandium can form two different structures. At room temperature, the most stable form of scandium is the hexagonal close-packed (HCP) structure α-scandium.[2] It is a fairly soft metallic material that can dissolve a moderate concentration of hydrogen, no more than 0.89 wt% at 22 °C. If scandium hydride contains more than 0.89% hydrogen at room temperature then it transforms into a face-centred cubic (FCC) structure, the δ-phase. It can dissolve considerably more hydrogen, as much as 4.29%, which reflects the upper hydrogen content of scandium hydride.

Research indicates the existence of a third phase created under extreme conditions termed the η-phase. This phase can dissolve as much as 6.30% hydrogen.

Concentration dependent activation-energies are observed for hydrogen diffusion in scandium metal.[3]

  1. ^ Chemistry of d-block elements G. Singh (2007)
  2. ^ Manchester, F. D.; Pitre, J. M. (1997). "The H- SC (Hydrogen- Scandium) system". Journal of Phase Equilibria. 18 (2): 194–205. ISSN 1054-9714. doi:10.1007/BF02665706. 
  3. ^ Weaver, H. (1972). "Nuclear-Magnetic-Resonance Investigation of Proton Motion in Scandium Hydride". Physical Review B. 5 (5): 1663–1667. ISSN 0556-2805. doi:10.1103/PhysRevB.5.1663. 

41xx steelAL-6XNAlGaAlloy 20AlnicoAlumelAlüminyumAlüminyum alaşımlarıAluminium bronzeAluminium-lithium alloyAmalgamArsenical bronzeArsenical copperBell metalBerilyumBeryllium copperBillon (alloy)BirmabrightBismanolBizmutPirinç (alaşım)BrightrayBronzBulat steelCalamine brassDökme demirCelestriumChinese silverChromelKromChromium hydrideKobaltColored goldConstantanBakırCopper hydrideCopper–tungstenCorinthian bronzeCrown goldCrucible steelCunifeCupronickelCymbal alloysŞam çeliğiDevarda's alloyDuraluminDutch metalElectrical steelElektrumElektron (metal)ElinvarFernicoFerroalloyFerroceriumFerrochromeFerromanganeseFerromolybdenumFerrosiliconFerrotitaniumFerrouraniumField's metalFlorentine bronzeGalfenolGalinstanGalyumGilding metalCamGlucydurAltınGuanín (bronze)GunmetalHaynes InternationalHepatizonHiduminiumHigh-speed steelHigh-strength low-alloy steelHydronaliumİnkomelİndiyumInvarDemirIron–hydrogen alloyItalmaKanthal (alloy)KovarKurşunLityumMagnaliumMagnezyumMagnox (alloy)MangalloyManganinMaraging steelMarine grade stainlessMartensitic stainless steelMegalliumMelchior (alloy)MercuryMischmetalMolybdochalkosMonelMu-metalMuntz metalMushet steelNichromeNikelNickel hydrideAlman gümüşüŞekil Hafızalı AlaşımlarNicrosilNisilKuzey altınıOrmoluPermalloyPhosphor bronzePig ironPinchbeck (alloy)PlastikPlexiglasPlütonyumPlutonium–gallium alloyPotasyumPseudo palladiumReynolds 531RhoditeRodyumRose's metalSamaryumSanicro 28SkandiyumShakudōGümüşSilver steelSodyumSodium-potassium alloySolderSpeculum metalSpiegeleisenSpring steelStaballoyPaslanmaz çelikÇelikStelliteStructural steelSupermalloySurgical stainless steelTerfenol-DTerneKalayTitanyumTombacTool steelTumbagaType metalUranyumVitalliumWeathering steelWood's metalWootz steelY alloyZeron 100ÇinkoZirkonyumSamarium–cobalt magnetArgentium sterling silverBritannia silverDoré bullionGoloidPlatinum sterlingShibuichiSom gümüşTibetan silverTitanium Beta CTitanium alloyTitanium hydrideGum metalTitanium goldTitanyum nitritBabbitt (alloy)Britannia metalPewterQueen's metalWhite metalUranium hydrideZamakZirconium hydrideHidrojenHelyumBorAzotOksijenFlorMetanMezzanineAtom

This article uses material from the Wikipedia article "", which is released under the Creative Commons Attribution-Share-Alike License 3.0. There is a list of all authors in Wikipedia

Material Database

database,rohs,reach,compliancy,directory,listing,information,substance,material,restrictions,data sheet,specification