about
Three-dimensional tracking of small aquatic organisms using fluorescent nanoparticlesAntibodies covalently immobilized on actin filaments for fast myosin driven analyte transportMechanochemical model for myosin V.Molecular motor propelled filaments reveal light-guiding in nanowire arrays for enhanced biosensing.Optical Trapping of Gold Nanoparticles in Air.Performance characteristics of Brownian motors.Bipolar Photothermoelectric Effect Across Energy Filters in Single Nanowires.Tracking actomyosin at fluorescence check pointsParallel computation with molecular-motor-propelled agents in nanofabricated networks.Reply to Einarsson: The computational power of parallel network exploration with many bioagents.The Tumbleweed: towards a synthetic proteinmotor.Design and construction of the lawnmower, an artificial burnt-bridges motor.Construction and characterization of kilobasepair densely labeled peptide-DNA.Dynamic guiding of motor-driven microtubules on electrically heated, smart polymer tracks.The fabrication of dense and uniform InAs nanowire arrays.Measuring temperature gradients over nanometer length scales.Characterization of Ambipolar GaSb/InAs Core-Shell Nanowires by Thermovoltage Measurements.Construction of a Chassis for a Tripartite Protein-Based Molecular Motor.Control and understanding of kink formation in InAs-InP heterostructure nanowires.Ultrafast molecular motor driven nanoseparation and biosensing.Effectiveness of beads for tracking small-scale molecular motor dynamics.Controlled microfluidic switching in arbitrary time-sequences with low drag.Intersubband Quantum Disc-in-Nanowire Photodetectors with Normal-Incidence Response in the Long-Wavelength Infrared.Single-nanowire, low-bandgap hot carrier solar cells with tunable open-circuit voltage.Conduction Band Offset and Polarization Effects in InAs Nanowire Polytype Junctions.Time-dependent motor properties of multipedal molecular spiders.Molecular motor transport through hollow nanowires.Realization of a feedback controlled flashing ratchet.Biased motion and molecular motor properties of bipedal spiders.Fully tunable, non-invasive thermal biasing of gated nanostructures suitable for low-temperature studies.Electron-beam patterning of polymer electrolyte films to make multiple nanoscale gates for nanowire transistors.Three key questions on fractal conductance fluctuations: Dynamics, quantization, and coherenceGeometry-independence of fractal ballistic processesDiscrete energy level spectrum dependence of fractal conductance fluctuations in semiconductor billiardsThe dependence of fractal conductance fluctuations on semiconductor billiard parametersThe dependence of fractal conductance fluctuations on soft-wall profile in a double-2DEG billiardEvolution of Fractal Patterns during a Classical-Quantum TransitionSemiconductor Billiards ? a Controlled Environment to Study FractalsDependence of fractal conductance fluctuations on soft-wall profile in a double-layer semiconductor billiardDetection of Single Actin Filaments at Fluorescence Interference Contrast Checkpoints
P50
Q27303113-D166858F-E7A5-4CDA-B7F3-D43F22726FA3Q27316404-1BA550F8-9D8D-4223-8BDC-D1F92D537B13Q30491555-6F848BAB-ED59-429D-A969-038A356FEA3BQ30571917-CC7B8027-055F-4142-95EF-F55E592847D4Q35666303-48FC12A2-BFD2-46DB-BA7B-7233DB4C4565Q36202930-79A2A788-29FF-43E9-8AA9-E3609E98F5CFQ36396811-4C8D30AA-590F-48A8-8B28-7A8AF8A903B1Q36547143-390F69B7-EC20-4922-AC89-B2D4C61DB703Q36684747-922D100B-B663-494A-B53F-9E32DDCAE24FQ37183686-A223D47B-304B-4F09-A127-EB52003C703CQ37272963-65D71050-9BD2-4C02-8E4F-6E9D3872E912Q39031450-1D819E6D-07C6-4FB5-AC1C-69106B38831BQ39127065-F4F5D98F-AD51-476F-9864-9EEC23DA55D9Q39404942-4A8BE185-03BF-484A-8402-8F353E8E2145Q39980560-B2CC1FCB-EA54-48D0-8618-867A6F70649EQ40008762-80C737E1-CC34-4112-80A9-DF9C70B33D31Q40820517-C58F8BC5-9CAB-44F6-AD05-59ADAF64085BQ41092265-196E6F77-2EBD-4B39-977E-2889F518AADDQ43584440-C173BEDA-3421-40CC-9AA7-A810C2C278BAQ44529632-2C889A56-7C8D-4C82-A25A-57C069C73FD5Q44858338-CDBD23A5-CC4B-4CB8-AA9C-87BD3020FA2DQ46979451-19C5A4EB-3E2A-494B-8500-154E27B5EE42Q47235572-E5F59556-5755-414A-BFDE-5257BB03AAAAQ47735017-A42E5028-446B-4C00-9706-3447D5C0BA2DQ48051259-50E361FF-1FCE-4062-B74D-602B2F8047E5Q51503685-4EFAC9E7-9F43-4EF0-B939-EA5AF2A88837Q51515129-C482E240-F3B3-41B4-89AC-7A7612A2A219Q51858699-A9CC98F0-1E26-442E-94D6-FE21666C87A4Q53066363-3F7CD7F6-5214-44FD-B189-8CA0D23F9615Q53153255-2C6E7D46-C1CC-4F02-836C-F28D70552A7AQ54454811-07399E21-1085-4A3E-A4EA-E11678716DC2Q56829260-0A707E4A-9659-40B9-9913-0BF2D3DEF82AQ56829284-DFDF93C0-9306-405B-9B56-2FFE15131F7BQ56829341-D0CD09F2-4227-40F7-BE42-9CC5C2CC1C75Q56829379-FF6B4D79-8157-4FB1-AB44-541B4E2CF0A9Q56829382-1C8D2948-CE76-41F2-9A9C-F80445594315Q56829393-6153B372-7F36-4591-B250-D450826AD489Q56829396-79DF15E7-088D-4702-B6CE-73D790D0CBE2Q56831909-24BC7FB6-9218-4000-A269-91AADC25081AQ57089640-471970CD-7FC0-4A96-B67A-8D640B8E85AB
P50
description
researcher ORCID ID = 0000-0003-4451-4006
@en
wetenschapper
@nl
name
H. Linke
@ast
H. Linke
@nl
Heiner Linke
@da
Heiner Linke
@de
Heiner Linke
@en
Heiner Linke
@fr
Heiner Linke
@nb
Heiner Linke
@nn
Heiner Linke
@sv
type
label
H. Linke
@ast
H. Linke
@nl
Heiner Linke
@da
Heiner Linke
@de
Heiner Linke
@en
Heiner Linke
@fr
Heiner Linke
@nb
Heiner Linke
@nn
Heiner Linke
@sv
prefLabel
H. Linke
@ast
H. Linke
@nl
Heiner Linke
@da
Heiner Linke
@de
Heiner Linke
@en
Heiner Linke
@fr
Heiner Linke
@nb
Heiner Linke
@nn
Heiner Linke
@sv
P214
P214
P31
P496
0000-0003-4451-4006
P7859
lccn-no2002042784