about
Understanding and controlling the structure and segregation behaviour of AuRh nanocatalystsMagnetic patterning: local manipulation of the intergranular exchange coupling via grain boundary engineering.Probing the oxidative etching induced dissolution of palladium nanocrystals in solution by liquid cell transmission electron microscopy.Normal modes and mode transformation of pure electron vortex beams.Non-destructive detection of cross-sectional strain and defect structure in an individual Ag five-fold twinned nanowire by 3D electron diffraction mapping.Atomic Defects in Two-Dimensional Materials: From Single-Atom Spectroscopy to Functionalities in Opto-/Electronics, Nanomagnetism, and Catalysis.Selective fusion, solvent dissolution, and local symmetry effects in inversion of colloidal crystals to ordered porous films.Three-dimensional atomic-scale structure of size-selected gold nanoclusters.Atomistic dynamics of sulfur-deficient high-symmetry grain boundaries in molybdenum disulfide.Direct Imaging of Kinetic Pathways of Atomic Diffusion in Monolayer Molybdenum Disulfide.Multivariate statistical analysis of electron energy-loss spectroscopy in anisotropic materials.Theoretical electron energy-loss spectroscopy and its application in materials research.Au–Rh and Au–Pd nanocatalysts supported on rutile titania nanorods: structure and chemical stabilityLow-temperature in situ large strain plasticity of ceramic SiC nanowires and its atomic-scale mechanismLarge-scale self-organized growth of (001) surface-oriented colloidal crystals by edge meniscus effectFivefold twinned boron carbide nanowiresLloyd, Babiker, and Yuan replyApplied physics: Bright electron twistersGolden single-atomic-site platinum electrocatalystsVorticity induced by chiral plasmonic fields
P50
Q28822016-1F34EF83-EBAD-49FC-9FFD-426773B55A8EQ35833959-17D5FE52-06B8-4787-BC2E-57531DF74D01Q36320490-6E248133-7B26-46EE-A94E-EC49FA10C11DQ39077430-6FEE97B5-D1A8-46BD-99E4-9A4E953E54B4Q39152350-1E53305F-F71C-4766-8E5F-903EC1500B69Q39179652-2A82328C-1789-4FE7-AE92-0F25F5563737Q43227582-12FC1C83-EFE5-4720-84B4-D863B76DC212Q47257975-BB868EC6-8280-45F4-B395-B3444FF10C45Q47930266-86A11C29-8856-4BF4-97BF-6A432CBE2B70Q48060789-12832E68-8920-422B-B9F2-1F9497D8DDBEQ50938855-99595858-2DFE-4CED-B571-ECDF06F24EE6Q51365774-46203AA5-3C0A-4760-80EF-478A82F2E583Q57610726-83E9C86B-C518-4973-8B5A-8E18EB6BD179Q79768746-332831AD-8F59-406D-9199-0268705F1224Q82889805-78882E54-1BFF-450B-AB4F-AAF5B9541DB4Q84420444-C089D885-27C6-4618-897E-A18891DD1459Q86819511-5B7F88F9-B679-458C-8F69-8CD9B2E0E3A7Q87786849-E7861652-5647-45A3-93AC-3BFA8CE20E27Q91704429-87C8FDC2-8596-4EF1-903F-956AC2989315Q91806075-B86DFF85-AB59-4007-92F6-D3371622A3AF
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Jun Yuan
@ast
Jun Yuan
@en
Jun Yuan
@es
Jun Yuan
@nl
Jun Yuan
@sl
type
label
Jun Yuan
@ast
Jun Yuan
@en
Jun Yuan
@es
Jun Yuan
@nl
Jun Yuan
@sl
prefLabel
Jun Yuan
@ast
Jun Yuan
@en
Jun Yuan
@es
Jun Yuan
@nl
Jun Yuan
@sl
P214
P1053
A-9726-2008
P106
P214
P31
P3829
P496
0000-0001-5833-4570
P735
P7859
viaf-305713504