about
Classical Hall effect in scanning gate experimentsQuantum Hall effect transition in scanning gate experimentsLow-temperature and high magnetic field dynamic scanning capacitance microscopeUltraclean single, double, and triple carbon nanotube quantum dots with recessed Re bottom gates.Magnetic field and contact resistance dependence of non-local charge imbalance.Near-unity Cooper pair splitting efficiency.Wet etch methods for InAs nanowire patterning and self-aligned electrical contacts.Magnetic Field Tuning and Quantum Interference in a Cooper Pair Splitter.Resonant and Inelastic Andreev Tunneling Observed on a Carbon Nanotube Quantum Dot.Optical imaging of electrical carrier injection into individual InAs quantum dots.Finite-bias Cooper pair splitting.Gigahertz Quantized Charge Pumping in Bottom-Gate-Defined InAs Nanowire Quantum Dots.Magnetoresistance engineering and singlet/triplet switching in InAs nanowire quantum dots with ferromagnetic sidegatesLocal electrical tuning of the nonlocal signals in a Cooper pair splitterg-factor anisotropy in nanowire-based InAs quantum dotsScanning Probe with Tuning Fork Sensor, Microfabricated Silicon Cantilever and Conductive Tip for Microscopy at Cryogenic TemperatureNonlocal spectroscopy of Andreev bound statesNew Generation of Moiré Superlattices in Doubly Aligned hBN/Graphene/hBN HeterostructuresNear-infrared optical investigations of snow, ice, and water layers on diffuse reflecting surfacesHighly symmetric and tunable tunnel couplings in InAs/InP nanowire heterostructure quantum dotsLarge spatial extension of the zero-energy Yu-Shiba-Rusinov state in a magnetic fieldIn Situ Strain Tuning in hBN-Encapsulated Graphene Electronic Devices
P50
Q21708413-00061652-37D5-4787-8C77-D740B2255976Q27341801-E2E82C52-ED15-428F-A128-8655E60B9C1BQ28308136-38DDCC7A-A5E2-4306-9690-F09E0ABFC06CQ46015429-158D794D-6F2F-4725-B344-D8A097789233Q50071250-4D481507-A010-436E-9742-BA83E4761AE0Q51306125-FAFF191C-AC95-4FE0-94B2-D4DE4E7796AEQ51397326-582CB713-13F3-411C-B2AF-4EBE7D7629D3Q51613480-3270F8E0-537E-45A5-8270-22332935B499Q51617912-49631943-5DC2-4576-95AC-CDBF354B6FD8Q53079222-C15FD1D9-91AD-46B4-B149-C75992B461D3Q53090447-10C5B97C-2564-446D-A7D0-4D44573E79CAQ53175080-0424BB08-3715-401B-9DBA-77C98CCBDD9BQ59443401-488A332C-4A5F-41FC-8F13-165CEE90E965Q59443426-35DCD799-6542-45F4-80CA-DF1E8D15B5C4Q59443448-2BBC27DB-7727-4294-B2A3-D43AB863AD89Q59445777-2982D35A-7A21-4A1D-BAD8-39A45C4A8B70Q59453983-C94D8FDA-E4CF-4015-B639-FFD1ECC48F11Q64106139-52569DFB-332B-42DD-B3EB-BFE109138C3DQ90838597-B3D1AD1A-3263-47D8-8491-64BF042FAF30Q91512326-1E1611D3-5E98-411E-979B-EC18B0FEB62BQ91891389-E04A95B3-3E18-49D8-80AD-E2B7B705D098Q92222917-041D4531-E43E-42FA-ADC9-59484CC7603E
P50
description
physicist at University of Basel
@en
wetenschapper
@nl
name
A Baumgartner
@nl
Andreas Baumgartner
@en
Andreas Baumgartner
@es
type
label
A Baumgartner
@nl
Andreas Baumgartner
@en
Andreas Baumgartner
@es
prefLabel
A Baumgartner
@nl
Andreas Baumgartner
@en
Andreas Baumgartner
@es
P106
P31
P496
0000-0003-4681-4926