1H-NMR measurements of proton mobility in nano-crystalline YSZ.Tuning the structural and physical properties of Cr2Ti3Se8 by lithium intercalation: a study of the magnetic properties, investigation of ion mobility with NMR spectroscopy and electronic band structure calculations.Self-diffusion of lithium in LiAlSi2O6 glasses studied using mass spectrometry.The ionic conductivity in lithium-boron oxide materials and its relation to structural, electronic and defect properties: insights from theory.Symmetry reduction due to gallium substitution in the garnet Li6.43(2)Ga0.52(3)La2.67(4)Zr2O12.Is Geometric Frustration-Induced Disorder a Recipe for High Ionic Conductivity?Lithium diffusion in congruent LiNbO3 single crystals at low temperatures probed by neutron reflectometry.Defibrillation of soft porous metal-organic frameworks with electric fields.Microscopic Li self-diffusion parameters in the lithiated anode material Li4 + xTi5O12 (0 < or = x < or = 3) measured by 7Li solid state NMR.Li7La3Zr2O12 Interface Modification for Li Dendrite Prevention.Li NMR Spectroscopy on Crystalline Li12Si7: Experimental Evidence for the Aromaticity of the Planar Cyclopentadienyl-Analogous Si56− RingsNonequilibrium structure of Zn2SnO4 spinel nanoparticlesStructure and dynamics of the fast lithium ion conductor “Li7La3Zr2O12”X-Ray Absorption Spectroscopy and Computer Modelling Study of Nanocrystalline Binary Alkaline Earth FluoridesSlow ion exchange in crystalline Li 2 SO 4 ⋅H 2 O: A 6 Li 2D EXSY NMR investigationNMR Studies of Lithium Diffusion in Li3(NH2)2I Over Wide Range of Li+ Jump RatesUsing light, X-rays and electrons for evaluation of the nanostructure of layered materialsFast dynamics ofH2Oin hydrous aluminosilicate glasses studied with quasielastic neutron scatteringMultinuclear NMR spectroscopic studies of structure and dynamics in hydrous NaAlSi3O8 and Ca0.5AlSi3O8 glassesHigh-resolution 27Al MAS NMR spectroscopic studies of the response of spinel aluminates to mechanical actionA One-Step Mechanochemical Route to Core−Shell Ca2SnO4Nanoparticles Followed by119Sn MAS NMR and119Sn Mössbauer SpectroscopyMechanosynthesis of the Fast Fluoride Ion Conductor Ba1–xLaxF2+x: From the Fluorite to the Tysonite StructureLi–Si thin films for battery applications produced by ion-beam co-sputteringLongitudinal spin relaxation in simple stochastic models for disordered systemsFrom ultraslow to fast lithium diffusion in the 2D ion conductor Li0.7TiS2 probed directly by stimulated-echo NMR and nuclear magnetic relaxationUltraslow Li diffusion in spinel-type structured Li4Ti5O12 - a comparison of results from solid state NMR and impedance spectroscopyNMR and impedance studies of nanocrystalline and amorphous ion conductors: lithium niobate as a model systemTracer diffusion measurements in solid lithium: a test case for the comparison between NMR in static and pulsed magnetic field gradients after upgrading a standard solid state NMR spectrometerMicroscopic access to long-range diffusion parameters of the fast lithium ion conductor Li7BiO6 by solid state 7Li stimulated echo NMREnhanced conductivity at the interface of Li2O:B2O3 nanocomposites: atomistic modelsPreparation by high-energy milling, characterization, and catalytic properties of nanocrystalline TiO2On the mechanisms of ionic conductivity in BaLiF3: a molecular dynamics studyInfluence of gas atmosphere and temperature on the conductivity and the photoconductivity of a TiO2 single crystal in the surface regionNMR relaxometry as a versatile tool to study Li ion dynamics in potential battery materialsHigh anion conductivity in a ternary non-equilibrium phase of BaF(2) and CaF(2) with mixed cationsFrom composites to solid solutions: modeling of ionic conductivity in the CaF2-BaF2 systemLi ion diffusion in the anode material Li12Si7: ultrafast quasi-1D diffusion and two distinct fast 3D jump processes separately revealed by 7Li NMR relaxometryExtremely slow Li ion dynamics in monoclinic Li2TiO3--probing macroscopic jump diffusion via 7Li NMR stimulated echoesMechanosynthesized nanocrystalline BaLiF(3): The impact of grain boundaries and structural disorder on ionic transportFrom micro to macro: access to long-range Li+ diffusion parameters in solids via microscopic (6, 7) Li spin-alignment echo NMR spectroscopy
P50
Q30681401-2B799618-C1F7-4AB3-AEB2-F814EBC4816DQ31139791-0B284C8F-7054-4BED-80BF-B3E5DF7AFED0Q34079429-98EF0C35-6B0C-4E7A-A16D-EE4864903C28Q38005884-0E9803E2-25AB-4EFD-B50E-9D1837375B47Q38786132-2C093411-777B-4847-B60A-EA7D3B64E7B9Q39210743-7B40A71C-9567-4617-8C09-C7DCBF7E9949Q46427163-F15030C4-DC57-4E68-9121-CB8D4FB35D76Q48159334-63D4B7F6-DF1E-46C8-B5ED-28F97E291AE9Q50854269-889BC9F3-6CCE-4F74-9BA9-797BAC412532Q51405992-F1693204-6DC6-468F-A883-46F4684087B1Q56172689-79D1C577-773D-48CC-B174-617A514C6EBAQ57528368-821982A0-D289-4533-A107-D24F252C73D3Q57907048-B00DC816-A446-41E4-BBD2-D9B0882AB632Q57962521-5E021F04-A50A-41D6-8A7D-D9E2E47BAB32Q58341461-30B5A2C9-8A93-4B6F-A252-D4DAE8863F42Q58341477-64CA197A-A649-4D2F-B5A1-E84116A928CAQ58586259-716A7C47-5FE0-4BD0-B0F1-6D92D33E3B4AQ58810141-8FAC49F4-45C5-4BF7-995B-1433F89659A9Q59725558-5C00AAD2-07C7-4E30-A878-CEC69C8095EDQ59725866-FDF7F557-F19B-4D1E-96BE-164FF6FBB2F6Q59726103-F37B82A2-CDA6-4FF7-A9C9-CD4E1E0273B1Q62684005-9DDDEFB2-1E6D-4633-95CF-68F65B5FAB77Q64176020-6B097987-6E54-4523-A65A-BECA70874AC6Q78143616-5FA6E8CD-68E6-4AD8-A891-37C93E810C9FQ79204132-12A95730-0ABC-4488-BB22-77B4ACE8B6D4Q79838946-938C1FE7-8423-4543-BB06-EFEABF3E0D96Q79840942-1771A0AC-4ED4-4CED-997B-D4AF8FBCF492Q80383347-EBBE0D6B-AECB-44D5-83FF-3D429F792B7BQ80600134-54E8F8D7-5314-43E1-9477-852E17F94F5CQ81427288-D91511E6-6D03-48B5-B9B4-AC9DEECF73AFQ82071147-389F26D4-50F6-4953-9561-284FFEA5ABFDQ82336390-28F0875B-7B5C-43B0-9993-B308B48E661CQ82569757-14FFCB48-D8A0-4193-A151-74F34EF7F447Q83511344-1536291B-9696-4429-A698-5CACD35B499FQ83659916-F69E3056-2B15-4A30-B060-6EE28A1B15FCQ83843904-4DB0E13C-B6BD-4755-B25E-9A22372B1B7FQ84219630-A580B8EA-3243-4D5C-815D-06053492DD0DQ84632571-31355F5C-ED39-4EAA-AA8B-A8EB50D0B02DQ84748971-A32BECC4-410A-4A50-9B0D-2825C7317019Q85003919-E20AE17C-9EBE-4007-8291-4EEB1E1AA408
P50
description
deutscher Physiker
@de
researcher, ORCID id # 0000-0003-1563-9176
@en
wetenschapper
@nl
name
Paul Heitjans
@ast
Paul Heitjans
@de
Paul Heitjans
@en
Paul Heitjans
@es
Paul Heitjans
@nl
type
label
Paul Heitjans
@ast
Paul Heitjans
@de
Paul Heitjans
@en
Paul Heitjans
@es
Paul Heitjans
@nl
prefLabel
Paul Heitjans
@ast
Paul Heitjans
@de
Paul Heitjans
@en
Paul Heitjans
@es
Paul Heitjans
@nl
P214
P227
P106
P1153
22997036200
P19
P21
P214
P227
1200416309
P31
P496
0000-0003-1563-9176
P569
1946-06-27T00:00:00Z
P735
P7859
lccn-no2006016559