about
Formation of novel transition metal hydride complexes with ninefold hydrogen coordinationReactive surface area of the Li(x)(Co(1/3)Ni(1/3)Mn(1/3))O2 electrode determined by μ(+)SR and electrochemical measurements.Li-ion diffusion inLi4Ti5O12andLiTi2O4battery materials detected by muon spin spectroscopyVariation of magnetic ground state ofSr1−xCaxCo2P2determined withμ+SRIn-Operando Neutron Diffraction Studies of Transition Metal Hydrogen Storage MaterialsPartially disordered spin structure in Ag2CrO2studied withμ+SRMicroscopic indicator for thermodynamic stability of hydrogen storage materials provided by muon-spin spectroscopyMicroscopic indicator for thermodynamic stability of hydrogen storage materials provided by positive muon-spin rotationMetallic Intermediate Hydride Phase of LaMg2Ni with Ni–H Covalent Bonding: Precursor State for Complex Hydride FormationTrue Boundary for the Formation of Homoleptic Transition-Metal Hydride ComplexesFormation of an Fe–H complex anion in YFe2: adjustment of imbalanced charge by using additional Li as an electron donorThermodynamical Stability of Complex Transition Metal Hydrides M2FeH6In-situ powder neutron diffraction study on the formation process of LaMg 2 NiH 7A novel inorganic solid state ion conductor for rechargeable Mg batteriesDehydriding and rehydriding properties of yttrium borohydride Y(BH4)3 prepared by liquid-phase synthesisFormation of an intermediate compound with a B12H12cluster: experimental and theoretical studies on magnesium borohydride Mg(BH4)2Experimental and computational studies on solvent-free rare-earth metal borohydridesR(BH4)3(R=Y, Dy, and Gd)Synthesis and Hydrogen Storage Properties of a Single-Phase Magnesium Borohydride Mg(BH 4 ) 2Hydrogen Absorption and Desorption by the Li−Al−N−H SystemSyntheses and Hydrogen Desorption Properties of Metal-Borohydrides M(BH 4 ) n (M=Mg, Sc, Zr, Ti, and Zn; n =2–4) as Advanced Hydrogen Storage MaterialsTheoretical study of Ti adsorption on Si(001) surfacesFirst-principles calculation of the structural, electronic, and vibrational properties of gallium nitride and aluminum nitride
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Q37695409-330E5EA1-999F-4ACD-A02A-942B0F4CCBA7Q43767901-3E974073-B566-424C-9EA1-162EA0EA70F6Q57960106-CB98CB2B-876C-4E67-BFEA-68AD84FE9932Q57960110-0D2AC183-944C-4625-8B69-EAEA54882B8FQ57960142-D773022F-F7D7-49FC-8751-4F6E8A7A85FFQ57960147-0EA438B0-844E-4F99-A7C9-6C63178520B6Q57960187-4D50CBD9-69B6-4695-99E4-C3DACE3D2D03Q57960188-FA91A500-946D-4597-B2EE-9B9565B53419Q58007737-F2A03BBA-224A-41A2-8EB0-06DD7AC5DBE5Q58007763-8D523EF8-85A4-469B-B5C6-7F46933432C1Q58007831-038F5E3D-ABC4-455C-96D9-87C1263B2F3AQ58007855-6DB762C2-1D33-40A4-B0AE-91311B36019AQ58050901-355DD3F2-FFBE-4D17-B270-9246CFAEC935Q58050915-EE4CE039-363B-4E45-8A49-C5D7105D8975Q58050962-C63D3BB7-C948-42C3-A63A-4C35DE2DE335Q58050963-8E1146FA-E1D7-47E9-8736-C9695D424B31Q58050980-1DBA570C-A47C-4BCA-BD65-BD6510CA02CBQ58051000-65E28955-9141-44E7-B247-CECC021C5954Q58051043-DC2E1D7B-01A7-4154-939F-48CC86CD9107Q58051048-9FE1C180-0F85-417E-B5B5-20EE89ABCD80Q58051106-44F04B8A-88C2-481E-85F6-BB92C5F38A05Q58051109-3BEE9A2F-1123-4DB9-9C2C-CF891F0FBB24
P50
description
Forscher
@de
chercheur
@fr
investigador
@es
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
研究者
@zh
name
Kazutoshi MIwa
@ast
Kazutoshi MIwa
@en
Kazutoshi MIwa
@es
Kazutoshi MIwa
@nl
type
label
Kazutoshi MIwa
@ast
Kazutoshi MIwa
@en
Kazutoshi MIwa
@es
Kazutoshi MIwa
@nl
prefLabel
Kazutoshi MIwa
@ast
Kazutoshi MIwa
@en
Kazutoshi MIwa
@es
Kazutoshi MIwa
@nl
P106
P1153
7202384697
P31
P496
0000-0002-9385-232X