about
Intermolecular contrast in atomic force microscopy images without intermolecular bondsMapping the electrostatic force field of single molecules from high-resolution scanning probe imagesNanoscale chemical imaging of a working catalyst by scanning transmission X-ray microscopy.Combination of Scanning Probe Microscopy and Coordination Chemistry: Structural and Electronic Study of Bis(methylbenzimidazolyl)ketone and Its Iron ComplexControlled lateral manipulation of molecules on insulating films by STM.Formation and characterization of a molecule-metal-molecule bridge in real space.Single-molecule chemistry and physics explored by low-temperature scanning probe microscopy.Electronic components embedded in a single graphene nanoribbon.Scanning probe microscopy and spectroscopy of colloidal semiconductor nanocrystals and assembled structures.Suppression of electron-vibron coupling in graphene nanoribbons contacted via a single atom.Characteristic Contrast in Δfmin Maps of Organic Molecules Using Atomic Force Microscopy.Quantitative atomic resolution force imaging on epitaxial graphene with reactive and nonreactive AFM probes.Experimental realization and characterization of an electronic Lieb lattice.Single-molecule synthesis and characterization of metal-ligand complexes by low-temperature STM.Controlling the orbital sequence in individual Cu-phthalocyanine molecules.Hole-induced electron transport through core-shell quantum dots: a direct measurement of the electron-hole interaction.Structure and local variations of the graphene moiré on Ir(111)Highly Luminescent Water-Soluble CdTe Quantum DotsOrbital and Charge-Resolved Polaron States in CdSe Dots and Rods Probed by Scanning Tunneling SpectroscopyLong-range orientation and atomic attachment of nanocrystals in 2D honeycomb superlatticesCuboidal Supraparticles Self-Assembled from Cubic CsPbBr Perovskite NanocrystalsRecognizing nitrogen dopant atoms in graphene using atomic force microscopyDesign and characterization of electrons in a fractal geometryBelieve in the forceMapping the Conductance of Electronically Decoupled Graphene NanoribbonsPrecursor Geometry Determines the Growth Mechanism in Graphene NanoribbonsTracking On-Surface Chemistry with Atomic PrecisionAryl Radical Geometry Determines Nanographene Formation on Au(111)Modeling the Self-Assembly of Organic Molecules in 2D Molecular Layers with Different StructuresSubmolecular Resolution Imaging of Molecules by Atomic Force Microscopy: The Influence of the Electrostatic ForceBending and buckling of narrow armchair graphene nanoribbons via STM manipulationSample Corrugation Affects the Apparent Bond Lengths in Atomic Force MicroscopyElectronic states in finite graphene nanoribbons: Effect of charging and defectsSymmetry Dependence of Vibration-Assisted TunnelingCharge State Control of Molecules Reveals Modification of the Tunneling Barrier with Intramolecular ContrastMolecular Symmetry Governs Surface DiffusionQuantitative Atomic Force Microscopy with Carbon Monoxide Terminated TipsNanoscale Chemical Imaging of the Reduction Behavior of a Single Catalyst ParticleH2Adsorption on 3d Transition Metal Clusters: A Combined Infrared Spectroscopy and Density Functional StudyIn Situ Synchrotron-Based IR Microspectroscopy To Study Catalytic Reactions in Zeolite Crystals
P50
Q28251597-6A8E19EA-AE3D-4FC2-A248-3935EE56F0A5Q28828884-985A3E5E-7F0E-4167-B66B-E32D95DA437CQ33441357-7CE6FCA1-3607-4FE9-BED5-EB84FE343A60Q33619628-2482949E-D061-45B7-9867-552AB43B5C18Q34129265-A2654C6E-9914-4811-B1A5-53C7FD73B28EQ34762617-3D66E7EE-C5BB-494B-AB68-28984BB45DA9Q37876296-8FAAB33C-BC6B-48C3-96D8-C15E35D5CE30Q38651903-296D5F38-6900-4ECD-8E71-7E82FA17D4D9Q38743692-77EDF886-F70F-41C5-8690-2002C22D6812Q39404139-1A899804-09D9-4263-B09E-E1270D734F46Q39504869-4DD89146-CF00-4D34-86CA-7F14009210B1Q39541560-67A28EF0-B9F4-49EA-A98D-13631CE3ED92Q42332231-38AB19D4-782E-4427-83EF-0D32E39AE1FAQ43043150-2F0CB558-8F31-4AC3-8F47-7C0A5395B890Q45812652-758C37F4-E804-46B9-9BAA-6C117A461C14Q53066758-8FA67FEB-197F-4DD4-8810-6627E6997D0EQ56030508-F0CDED1F-8007-4A9D-81D6-FCD0C9345B12Q57330475-FCF9CDBB-A192-41B0-9286-14305A23F630Q57353509-7497A8A9-DEAB-4CDD-B3BD-CEE77DD34198Q59987986-B86280E4-16D5-4319-A982-C3B848426080Q60022699-43E7F5DF-CF55-48D6-AD1A-91B23C0C8253Q60179535-9EC83FB0-D0C2-4238-B59C-A2F81476B0FBQ62112226-FBE9BA7B-8397-4157-9DC8-3195743C682CQ62112228-E50FA526-CBB2-49A4-A36B-F7BBE1F20155Q62112230-9CCFFFF0-C4C3-4DC0-B416-F0F5AD2AA4C6Q62112233-3376C7F8-67C5-4B12-B73F-A00D4A8B4581Q62112234-185CA825-B7D0-443B-B5CE-2C5B3EC27A98Q62112236-CDB7FF63-DDBC-4C8A-8CA6-125BC14213B3Q62112238-EBC4E8D1-4B3A-4767-9549-7D4733F9C83EQ62112239-74CE78CE-FA58-4D15-A1D0-7D1E7A5D8AB7Q62112241-0800E606-3661-42CA-AD8A-83A527AC20CCQ62112242-31E65014-67CA-49DB-8524-E73756612A7CQ62112244-350F5A85-1219-431B-8A94-389A07FB7E7EQ62112246-587CB04F-46A5-41D6-AD15-9FEE0F4F58A1Q62112247-BF5C2608-9CFC-441A-BDBB-BB8226EFE7C6Q62112248-D597CCA0-98F3-4A28-9F20-115D0B7AF2F8Q62112249-7EF5295A-4B9F-4045-BFD0-188388A1F7D0Q62112251-36FB29D3-8CF2-4AA9-BD49-5BAE3E703656Q62112253-471BF834-95EA-4AEA-B6BD-A3023E61FADFQ62112254-804BBF38-6D71-41DE-B548-2D4922A6A28A
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Ingmar Swart
@ast
Ingmar Swart
@en
Ingmar Swart
@es
Ingmar Swart
@nl
type
label
Ingmar Swart
@ast
Ingmar Swart
@en
Ingmar Swart
@es
Ingmar Swart
@nl
altLabel
I. Swart
@nl
prefLabel
Ingmar Swart
@ast
Ingmar Swart
@en
Ingmar Swart
@es
Ingmar Swart
@nl
P106
P1153
23670705300
P31
P496
0000-0003-3201-7301
P734
P7449
PRS1302024