about
Towards multi-order hard X-ray imaging with multilayer zone plates.Current-voltage characterization of individual as-grown nanowires using a scanning tunneling microscopePhoton upconversion in degenerately sulfur doped InP nanowires.Au-seeded growth of vertical and in-plane III-V nanowires on graphite substrates.Electron trapping in InP nanowire FETs with stacking faults.A new route toward semiconductor nanospintronics: highly Mn-doped GaAs nanowires realized by ion-implantation under dynamic annealing conditions.Simulated sample heating from a nanofocused X-ray beam.Structural investigation of GaInP nanowires using X-ray diffraction.Simultaneous high-resolution scanning Bragg contrast and ptychographic imaging of a single solar cell nanowire.InP nanowire array solar cells achieving 13.8% efficiency by exceeding the ray optics limit.Fluorescent nanowire heterostructures as a versatile tool for biology applications.Semiconductor-oxide heterostructured nanowires using postgrowth oxidation.Electrical and optical properties of InP nanowire ensemble p⁺-i-n⁺ photodetectors.Bending and Twisting Lattice Tilt in Strained Core-Shell Nanowires Revealed by Nanofocused X-ray Diffraction.Probing the wurtzite conduction band structure using state filling in highly doped InP nanowires.Holographic imaging with a hard x-ray nanoprobe: ptychographic versus conventional phase retrieval.In Operando X-Ray Nanodiffraction Reveals Electrically Induced Bending and Lattice Contraction in a Single Nanowire Device.Spectrally resolved x-ray beam induced current in a single InGaP nanowireBragg coherent x-ray diffractive imaging of a single indium phosphide nanowireConfinement effects on Brillouin scattering in semiconductor nanowire photonic crystalStrategies to obtain pattern fidelity in nanowire growth from large-area surfaces patterned using nanoimprint lithographyCarrier Recombination Dynamics in Sulfur-Doped InP NanowiresBulk-like transverse electron mobility in an array of heavilyn-doped InP nanowires probed by terahertz spectroscopyStudy of photocurrent generation in InP nanowire-based p+-i-n+ photodetectorsLarge-energy-shift photon upconversion in degenerately doped InP nanowires by direct excitation into the electron gasSolid–liquid–vapor metal-catalyzed etching of lateral and vertical nanoporesParticle-assisted GaxIn1−xP nanowire growth for designed bandgap structuresSingle GaInP nanowire p-i-n junctions near the direct to indirect bandgap crossover pointTunnel Field-Effect Transistors Based on InP-GaAs Heterostructure NanowiresDegenerate p-doping of InP nanowires for large area tunnel diodesDoping profile of InP nanowires directly imaged by photoemission electron microscopyDual-gate induced InP nanowire diodeDynamics of extremely anisotropic etching of InP nanowires by HClFabrication and characterization of AlP-GaP core-shell nanowiresGate-Induced Fermi Level Tuning in InP Nanowires at Efficiency Close to the Thermal LimitGrowth of doped InAsyP1−y nanowires with InP shellsNanowires With Promise for PhotovoltaicsPhotovoltaics with piezoelectric core-shell nanowiresHigh-Performance Single Nanowire Tunnel DiodesIn situ etching for total control over axial and radial nanowire growth
P50
Q30652830-2227F1B2-7A75-46AE-9A5D-F4859B12AB23Q34995410-186246F4-E71C-4330-8C75-128EE79B885FQ35846433-6C5DDDA5-7EEA-4567-9A75-F4881D9BBFBBQ38732437-37AC8866-2139-4898-B4E4-83275B744453Q39678130-2113CF21-C109-46E7-A407-47DF119ED156Q39716761-F8C89815-411A-461A-AD87-A738375CA4DCQ41591225-03FBBDA2-6EB3-4F1C-B102-65B6E54A5B34Q41996655-83D89AC1-6CE5-448C-ABFF-8E3BBA1653A9Q43147715-AA734126-0A67-4A8A-8675-D868A3EA3279Q44629622-A0465DF7-0F04-453A-9042-CC0FA816BEB9Q45215235-0C8A4A94-555E-454D-BB56-C56471281CA3Q46186584-2C9C3661-A940-4D61-B0D3-2F08F3854CFFQ46629369-493F0161-D3DC-4716-991B-0D4B1E1E8A62Q48278399-F7F415E6-B164-4E55-BDC2-211846452436Q50277400-B889EF35-687F-426A-9F61-88F3B9A871DBQ50541200-3C4AA861-4B41-44EA-A02B-6A1F9DA681BCQ51598580-8651F922-66F2-47E2-B17D-D228885AB0E9Q57629719-B3C48262-73FF-40DE-B78B-F834FFACA45FQ57629733-B22CB667-438D-46A7-9CDD-8128DC94934AQ57629734-53A563B4-BDF4-437B-BAE8-AE41876B00DEQ57629736-1CB00268-06A5-4214-A22A-9463E151F1D7Q57629738-47B5C70B-7120-4863-B7ED-D64D17560571Q57629744-17A4D8F8-9856-489E-81D7-7A67B6146BA7Q57629778-7B61AD63-53AE-46C0-BB6A-BE070B63F432Q57629792-0A4B80B1-B06B-4A1A-BD26-C3D7D9EE7889Q57629795-71F9BD87-5F04-45B2-B7B9-2E15151C1F63Q57629796-1083BC3A-642F-4EFD-8399-37378309A7B3Q57629797-973DA9B0-4A6D-4808-9966-904C3DF1A2CAQ57629798-ECC99FF5-1D23-4DAE-B2B8-0C8E9EC44ED0Q57629800-1DEB96A8-113B-4E2D-9D92-7F9A6CEFD10EQ57629803-D47E619A-7DAB-44EC-B713-7F2CB8C150DEQ57629804-0FDFA573-1CE1-4810-ACB3-3F722174585DQ57629805-6AF4EB5A-87EB-4BAF-9B4F-E59977E2667BQ57629806-90BD54E9-E36C-4C15-AF6B-CBEFF55CC685Q57629807-BE8BE005-BC96-4AFB-BAE4-4B458F13A1E4Q57629808-361195BB-59AC-4C2E-8587-8461A53915D7Q57629809-F01FF711-D36D-43BE-8B7D-1012D4100036Q57629810-39F748C6-CDF4-44BF-929E-521E0AD49A2FQ57629824-26229375-7289-47BF-B8E4-C072B7D45BDCQ57629828-9945C823-2A26-47EC-A522-70EC72963867
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Jesper Wallentin
@ast
Jesper Wallentin
@en
Jesper Wallentin
@es
Jesper Wallentin
@nl
Jesper Wallentin
@sl
type
label
Jesper Wallentin
@ast
Jesper Wallentin
@en
Jesper Wallentin
@es
Jesper Wallentin
@nl
Jesper Wallentin
@sl
prefLabel
Jesper Wallentin
@ast
Jesper Wallentin
@en
Jesper Wallentin
@es
Jesper Wallentin
@nl
Jesper Wallentin
@sl
P1053
A-7265-2010
P106
P108
P21
P31
P3829
P496
0000-0001-5909-0483