about
Diffraction of Complex Molecules by Structures Made of LightQuantum interference of large organic moleculesMatter-Wave Interferometer for Large MoleculesAtomic Wave Diffraction and Interference Using Temporal SlitsCollisional Decoherence Observed in Matter Wave InterferometryWave Nature of Biomolecules and FluorofullerenesWave-particle duality of C(60) moleculesQuantum physics meets biologyLaser-induced acoustic desorption of natural and functionalized biochromophores.Cavity cooling of free silicon nanoparticles in high vacuum.Gas-phase formation of large neutral alkaline-earth metal tryptophan complexes.A superconducting NbN detector for neutral nanoparticles.Decoherence of matter waves by thermal emission of radiation.Matter-wave interference of particles selected from a molecular library with masses exceeding 10,000 amu.Experimental methods of molecular matter-wave optics.Stability of high-mass molecular libraries: the role of the oligoporphyrin coreCoherence in the presence of absorption and heating in a molecule interferometer.Cavity-Assisted Manipulation of Freely Rotating Silicon Nanorods in High Vacuum.Single-photon ionization of organic molecules beyond 10 kDa.Selective photodissociation of tailored molecular tags as a tool for quantum optics.In search of multipath interference using large molecules.Quantum-Assisted Metrology of Neutral Vitamins in the Gas Phase.Toward Two-Dimensional All-Carbon Heterostructures via Ion Beam Patterning of Single-Layer Graphene.New avenues for matter-wave-enhanced spectroscopy.Tailoring the volatility and stability of oligopeptides.Immobilization of zinc porphyrin complexes on pyridine-functionalized glass surfaces.Erratum: Coherence in the presence of absorption and heating in a molecule interferometer.Sublimation enthalpy of dye molecules measured using fluorescence.Long-pulse laser launch and ionization of tailored large neutral silver nanoparticles with atomic mass assignment.Optically driven ultra-stable nanomechanical rotor.Gas phase sorting of fullerenes, polypeptides and carbon nanotubes.Tailored photocleavable peptides: fragmentation and neutralization pathways in high vacuum.Photofragmentation beam splitters for matter-wave interferometry.From coherent to noise-induced microwave ionization of Rydberg atoms.Quantum technology: from research to applicationQuantum interference experiments with large moleculesRealization of optical carpets in the Talbot and Talbot-Lau configurationsColloquium: Quantum interference of clusters and moleculesTesting the limits of quantum mechanical superpositionsWave and Particle in Molecular Interference Lithography
P50
Q21563697-A9A5470C-9945-4CB0-A1B1-12FE7ACB2AAAQ24629921-90CCDEEC-1029-4425-860A-ED9612253D09Q27343009-7FA012AC-29A9-41CB-B263-88EBEB708D9FQ27450575-59F51369-74BF-47DE-BA0D-5CBEE0EE4B26Q27450908-B6EA2720-775C-40CE-BFD3-ACC2369585E1Q27450943-842CEB62-31AC-4180-B3D8-43DFC6B3E64CQ28280808-63ACCF29-D649-4A61-B550-E4EC1FC78602Q28748491-3DE5D0E4-A14E-4F53-A215-F409C850AAF5Q30409841-F9BA7989-470D-4BC3-BAD9-EC9A3DBD20F8Q30447101-545EA5BF-4D28-43CE-A35E-72F0B9ED1FD2Q30843932-47B05C14-2D52-4FD2-B9F8-024B4993DB4DQ33509971-DBA36D26-E269-4CAC-8B94-61139D1F5C29Q34299764-0BD63664-5ECB-4696-9A4A-1B36AFD150EBQ34360813-382871A6-6868-4BE9-928D-EAC9CAC6616DQ34888605-F7BA3CE1-0CF9-4343-B19E-A9591BDAD6D7Q35066155-1C9F77C8-A215-4EBB-940F-0CD1C2A3E35AQ35661058-6A6A4344-0718-4887-BCDA-00F956AB5A40Q35689316-8CAEA8A0-64A8-4194-8277-20B29F236E3BQ36754056-5358D701-E393-4AD3-91E0-985C7516CA1FQ37635475-D263832E-33D6-4FF3-BBDE-BCD917C8DB1CQ41363673-22D6842C-EAF2-4706-8CDB-B214FA22E5E1Q41602120-DE78F977-A510-445B-BD7A-E0B2D6B215EFQ42145284-2AB91BB9-E185-4DEF-93E0-874958F37963Q42355176-B72A5C72-977D-4265-8C4A-1744BFCE0280Q42359684-6530E168-F41F-4179-B38A-F1C88D560914Q43125239-7492495B-26A2-46C6-BD73-321577784EC7Q43136655-A31570D9-3F4C-4609-938C-16A14EF81845Q45097702-8B914BA6-F805-47EF-917B-A30BED51AD6DQ46344563-688B7CB7-F8E3-40BB-B853-56CC1B027822Q47129630-711090B3-CC4F-4B59-B64C-9D101AA9724AQ47957239-28A4B467-09D3-47A4-8C6E-CBF0FB9AE39FQ52323986-20FE587B-C182-4C6C-A2DF-3D1B4B04DDD5Q53657302-144CD0F2-942F-4AF0-8D4A-F6A97E8D0163Q54132103-E97131BC-3CA8-415A-A378-D071EBF94692Q54310276-5293B466-7219-481A-8A83-6A95D4F4FA84Q55896503-C795D1CB-1BC1-4C64-8B73-E1DA60C93289Q56003264-558D1179-9286-4493-BBAC-1984C9027D86Q56144191-F217C557-5237-402B-B0E6-F1E4930FF24EQ56508929-ADF63380-5308-4AB9-B704-554C0BFCD2A7Q56636755-73D7D959-D512-455C-A6AB-A7BA962D1A81
P50
description
Duits natuurkundige
@nl
German physicist
@en
German physicist
@en-ca
German physicist
@en-gb
Saksamaa füüsik
@et
deutscher Physiker, Universitätsprofessor für Quantennanophysik an der Universität Wien
@de
fisiceoir Gearmánach
@ga
fizician german
@ro
fizikan gjerman
@sq
físic alemany
@ca
name
Markus Arndt
@ast
Markus Arndt
@ca
Markus Arndt
@da
Markus Arndt
@de
Markus Arndt
@en
Markus Arndt
@es
Markus Arndt
@fr
Markus Arndt
@it
Markus Arndt
@nb
Markus Arndt
@nds
type
label
Markus Arndt
@ast
Markus Arndt
@ca
Markus Arndt
@da
Markus Arndt
@de
Markus Arndt
@en
Markus Arndt
@es
Markus Arndt
@fr
Markus Arndt
@it
Markus Arndt
@nb
Markus Arndt
@nds
prefLabel
Markus Arndt
@ast
Markus Arndt
@ca
Markus Arndt
@da
Markus Arndt
@de
Markus Arndt
@en
Markus Arndt
@es
Markus Arndt
@fr
Markus Arndt
@it
Markus Arndt
@nb
Markus Arndt
@nds
P214
P227
P1053
A-4571-2012
P1412
P1556
arndt.markus
P1559
Markus Arndt
@de
P19
P21
P213
0000 0004 4892 9388
P214
P227
1051164249
P31
P3829
P496
0000-0002-9487-4985
P569
1965-09-14T00:00:00Z