Publikationen von Dr. Arne Ludwig
2025
[1] Shutter-Synchronized Molecular Beam Epitaxy for Wafer-Scale Homogeneous GaAs and Telecom Wavelength Quantum Emitter Growth
E. Kersting u. a.
Nanomaterials, Bd. 15, Nr. 3, Jan. 2025
[2] Author Correction: A single-photon emitter coupled to a phononic-crystal resonator in the resolved-sideband regime
C. Spinnler u. a.
Nature communications, Bd. 16, Nr. 1, März 2025
[3] Electronic interferometry with ultrashort plasmonic pulses
S. Ouacel u. a.
Nature communications, Bd. 16, Nr. 1, Mai 2025
[4] Evidence of Coulomb liquid phase in few-electron droplets
J. Shaju u. a.
Nature, Bd. 2025, S. 928–933, Juni 2025
[5] Resonant energy transfer and collectively driven emitters in waveguide QED
C. J. van Diepen u. a.
Physical Review Research [ISSN: 2643-1564], Bd. 7, Nr. 3, Aug. 2025
[6] A Coherent and Efficient One-Dimensional Atom
A. Javadi u. a.
in Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition, Jan. 2025.
[7] Magnetic tuning of the tunnel coupling in an optically active quantum dot molecule
F. Bopp u. a.
Physical review B, Bd. 112, Nr. 6, Aug. 2025
[8] Quantum stochastic resonance in a single-photon emitter
H. Mannel u. a.
Communications Physics [ISSN: 2399-3650], Bd. 8, Nr. 1, Okt. 2025
[9] Integration of a GaAs -based nanomechanical phase shifter with quantum-dot single-photon sources
C. Qvotrup u. a.
Physical Review Applied [ISSN: 2331-7019], Bd. 24, Nr. 5, Juli 2025
[10] Eigenstate control of plasmon wavepackets with electron-channel blockade
S. Takada u. a.
Nature Communications [ISSN: 2041-1723], Bd. 16, Nr. 1, Nov. 2025
[11] Optical and Magnetic Response by Design in GaAs Quantum Dots
C. Schimpf u. a.
PRX quantum, Bd. 6, Nr. 4, Okt. 2025
[12] Electrical Control of Quantum-Dot Single-Photon Source on SiO2/Si Substrate
H. Salamon u. a.
in 2025 Conference on Lasers and Electro-Optics (CLEO): Applications and Technology, Long Beach, Jan. 2025.
[13] Resonant and antiresonant exciton-phonon coupling in quantum dot molecules
M. Lienhart u. a.
Physical Review B [ISSN: 2469-9950], Bd. 112, Nr. 23, Nov. 2025
[14] Programmable nonlinear quantum photonic circuits
K. H. Nielsen u. a.
Nature Communications [ISSN: 2041-1723], Dez. 2025
2024
[1] Quantum key distribution using deterministic single-photon sources over a field-installed fibre link
M. Zahidy u. a.
npj Quantum information, Bd. 10, Nr. 1, Jan. 2024
[2] The interplay between electron tunneling and Auger emission in a single quantum emitter weakly coupled to an electron reservoir
M. Zöllner u. a.
Applied physics letters, Bd. 124, Jan. 2024
[3] Accelerated adiabatic passage of a single electron spin qubit in quantum dots
X.-F. Liu, Y. Matsumoto, T. Fujita, A. Ludwig, A. Wieck, und A. Oiwa
Physical review letters, Bd. 132, Jan. 2024
[4] Curved GaAs cantilever waveguides for the vertical coupling to photonic integrated circuits
C. Qvotrup, Z. Liu, C. Papon, A. Wieck, A. Ludwig, und L. Midolo
Optics express, Bd. 32, Nr. 3, S. 3723–3734, Jan. 2024
[5] On-demand single-electron source via single-cycle acoustic pulses
S. Ota u. a.
Physical review applied, Bd. 21, Nr. 2, Feb. 2024
[6] Machine learning enhanced evaluation of semiconductor quantum dots
E. Corcione u. a.
Scientific reports, Bd. 14, Nr. 1, Feb. 2024
[7] Electrical resistance associated with the scattering of optically oriented spin-polarized electrons in n -GaAs
M. D. Ragoza u. a.
Physical review B, Bd. 109, Nr. 12, März 2024
[8] Quantum dot coupled to a suspended-beam mechanical resonator : from the unresolved- to the resolved-sideband regime
C. Spinnler u. a.
Physical review applied, Bd. 21, März 2024
[9] Electrical control of a Kondo spin screening cloud
N. H. Tu u. a.
18. April 2024.
[10] Complete quantum control of orbital qubits by phase-controlled stimulated Raman transitions
J.-Y. Yan u. a.
22. März 2024.
[11] Dynamics of quantum cellular automata electron transition in triple quantum dots
T. Aizawa u. a.
10. März 2024.
[12] Realisation of a coherent and efficient one-dimensional atom
N. Tomm u. a.
19. Februar 2024.
[13] Towards charge tunable quantum dot circular Bragg gratings
Q. Buchinger u. a.
in Quantum Computing, Communication, and Simulation IV, San Francisco, März 2024, Bd. 12911
[14] Visual explanations of machine learning model estimating charge states in quantum dots
Y. Muto u. a.
APL machine learning, Bd. 2, Nr. 2, Apr. 2024
[15] Mastering quantum emitter analysis : device characterization in the single-photon limit
M. Sifft u. a.
in Bulletin of the American Physical Society, Minneapolis & Virtual, 2024
[16] Electron capture dynamics into self-assembled quantum dots far from equilibrium with their environment
L. Berg u. a.
Physical review B, Bd. 109, Juni 2024
[17] Mo-Si superconducting nanowire single-photon detectors on GaAs
M. Erbe u. a.
Physical review applied, Bd. 22, Nr. 1, Juli 2024
[18] Critical Aluminum Etch Material Amount for Local Droplet-Etched Nanohole-Based GaAs Quantum Dots
T. Kruck, H.-G. Babin, A. Wieck, und A. Ludwig
Crystals, Bd. 14, Nr. 8, Aug. 2024
[19] Realization of a Coherent and Efficient One-Dimensional Atom
N. Tomm u. a.
Physical review letters, Bd. 133, Nr. 8, Aug. 2024
[20] Direct observation of a few-photon phase shift induced by a single quantum emitter in a waveguide
M. J. R. Staunstrup u. a.
Nature communications, Bd. 15, Nr. 1, Aug. 2024
[21] Deterministic photon source of genuine three-qubit entanglement
Y. Meng u. a.
Nature communications, Bd. 15, Nr. 1, Sep. 2024
[22] High-fidelity spin readout via the double latching mechanism
H. Kiyama, D. van Hien, A. Ludwig, A. Wieck, und A. Oiwa
npj Quantum information, Bd. 10, Nr. 1, Okt. 2024
[23] A single-photon emitter coupled to a phononic-crystal resonator in the resolved-sideband regime
C. Spinnler u. a.
Nature communications, Bd. 15, Nr. 1, Nov. 2024
[24] All-Optical Ultrafast Arbitrary Rotation of Hole Orbital Qubits with Direct Phase Control
J.-Y. Yan u. a.
Physical review letters, Bd. 133, Nr. 20, Nov. 2024
[25] Telecom O-Band Quantum Dots Fabricated by Droplet Etching
N. Spitzer u. a.
Crystals, Bd. 14, Nov. 2024
[26] Dynamics of quantum cellular automata electron transition in triple quantum dots
T. Aizawa u. a.
Physical review B, Bd. 110, Nr. 23, Dez. 2024
[27] Nanocavity-based quantum-dot single-photon source on a SiN waveguide integrated by transfer printing
N. Pholsen u. a.
Optics express, Bd. 33, Nr. 1, S. 252–262, Dez. 2024
[28] Wavelength-tunable high-fidelity entangled photon sources enabled by dual Stark effects
C. Chen u. a.
Nature communications, Bd. 15, Nr. 1, Juli 2024
[29] Nanomechanical Phase Shifting on a Gallium Arsenide Platform
C. Qvotrup u. a.
in The 25th European Conference on Integrated Optics, Aachen, Jan. 2024, Bd. 402, S. 289–292
[30] Sensing dot with high output swing for scalable baseband readout of spin qubits
E. Kammerloher u. a.
Physical review applied, Bd. 22, Nr. 2, Aug. 2024
[31] Quantum polyspectra approach to the dynamics of blinking quantum emitters at low photon rates without binning: Making every photon count
M. Sifft u. a.
Physical review A, Bd. 109, Nr. 6, Juni 2024
[32] Violation of Bell inequality by photon scattering on a two-level emitter
S. Liu u. a.
Nature physics, Bd. 20, Nr. 9, S. 1429–1433, Juni 2024
[33] Heterogeneous Integration of GaAs Waveguides with Silicon Nitride Photonic Integrated Circuits
A. Shadmani u. a.
in Quantum 2.0 in Proceedings Quantum 2.0 Conference and Exhibition, Jan. 2024
[34] Programmable Photonic Nonlinearity for Quantum Simulation
Y. Wang u. a.
in 2024 Asia Communications and Photonics Conference (ACP) and International Conference on Information Photonics and Optical Communications (IPOC), Nov. 2024, S. 15
[35] A Coherent and Efficient One-Dimensional Atom
A. Javadi u. a.
in Laser Science, LS 2024 in Proceedings Frontiers in Optics + Laser Science 2024 (FiO, LS) - Part of Frontiers in Optics + Laser Science 2024, Jan. 2024.
[36] Efficient and deterministic InAs/GaAs quantum dot single-photon source emitting directly in the original telecommunications band (O-band)
M. Albrechtsen u. a.
in Frontiers in Optics, FiO 2024 in Proceedings Frontiers in Optics + Laser Science 2024 (FiO, LS) - Part of Frontiers in Optics + Laser Science 2024, Jan. 2024.
[37] A Coherent and Efficient One-Dimensional Atom
A. Javadi u. a.
in Frontiers in Optics, FiO 2024 in Proceedings Frontiers in Optics + Laser Science 2024 (FiO, LS) - Part of Frontiers in Optics + Laser Science 2024, Jan. 2024.
2023
[1] Collective super- and subradiant dynamics between distant optical quantum emitters
A. Tiranov u. a.
Science, Bd. 379, Nr. 6630, S. 389–393, Jan. 2023
[2] Anomalous screening effect of superlattice-doped GaAs / (Al,Ga)As heterostructures under illumination
X.-F. Liu, N. Spitzer, H. Kiyama, A. Ludwig, A. Wieck, und A. Oiwa
Physical review applied, Bd. 19, Feb. 2023
[3] Complete readout of two-electron spin states in a double quantum dot
M. Nurizzo u. a.
PRX quantum, Bd. 4, März 2023
[4] Photon bound state dynamics from a single artificial atom
N. Tomm u. a.
Nature physics, Bd. 19, S. 857–862, März 2023
[5] Coulomb-mediated antibunching of an electron pair surfing on sound
J. Wang u. a.
Nature nanotechnology, Bd. 18, S. 721–726, Mai 2023
[6] High-speed thin-film lithium niobate quantum processor driven by a solid-state quantum emitter
P. I. Sund u. a.
Science advances, Bd. 9, Nr. 19, Mai 2023
[7] Cavity-enhanced excitation of a quantum dot in the picosecond regime
A. Javadi u. a.
31. Januar 2023.
[8] Coherent driving of direct and indirect excitons in a quantum dot molecule
F. Bopp u. a.
2023.
[9] Deterministic photon source interfaced with a programmable silicon-nitride integrated circuit
Y. Wang u. a.
13. Februar 2023.
[10] Independent electrical control of two quantum dots coupled through a photonic-crystal waveguide
X.-L. Chu u. a.
1. März 2023.
[11] Magnetic tuning of the tunnel coupling in an optically active quantum dot molecule
F. Bopp u. a.
22. März 2023.
[12] Tailoring potentials by simulation-aided design of gate layouts for spin qubit applications
I. Seidler u. a.
23. März 2023.
[13] On-chip spin-photon entanglement based on photon-scattering of a quantum dot
M. L. Chan u. a.
npj Quantum Information, Mai 2023
[14] Independent operation of two waveguide-integrated quantum emitters
C. Papon u. a.
Physical review applied, Bd. 19, Nr. 6, Juni 2023
[15] Cavity-enhanced single-shot readout of a quantum dot spin within 3 nanoseconds
N. O. Antoniadis u. a.
Nature communications, Bd. 14, Nr. 1, Juli 2023
[16] Independent electrical control of two quantum dots coupled through a photonic-crystal waveguide
X.-L. Chu u. a.
Physical review letters, Bd. 131, Nr. 3, Juli 2023
[17] Coherent control of a high-orbital hole in a semiconductor quantum dot
J.-Y. Yan u. a.
Nature nanotechnology, Bd. 18, Nr. 10, S. 1139–1146, Juli 2023
[18] Cavity-enhanced excitation of a quantum dot in the picosecond regime
A. Javadi u. a.
New journal of physics, Bd. 25, Sep. 2023
[19] Deterministic photon source interfaced with a programmable silicon-nitride integrated circuit
Y. Wang u. a.
npj Quantum information, Bd. 9, Nr. 1, Sep. 2023
[20] Auger and spin dynamics in a self-assembled quantum dot
H. Mannel u. a.
Journal of applied physics, Bd. 134, Nr. 15, Okt. 2023
[21] Tailoring potentials by simulation-aided design of gate layouts for spin-qubit applications
I. Seidler u. a.
Physical review applied, Bd. 20, Nr. 4, Okt. 2023
[22] Elektrische Spin Injektion in kantenemittierenden Halbleiterlasern
N. Jung u. a.
Okt. 2023.
[23] Wafer-scale emission energy modulation of indium flushed quantum dots
N. Spitzer, N. Bart, H.-G. Babin, M. Schmidt, A. Wieck, und A. Ludwig
Crystals, Bd. 13, Nr. 12, Nov. 2023
[24] Symmetry breaking via alloy disorder to explain radiative Auger transitions in self-assembled quantum dots
K. Gawarecki u. a.
Physical review B, Bd. 108, Nr. 23, 2023
[25] Photonic fusion of entangled resource states from a quantum emitter
Y. Meng u. a.
14. Dezember 2023.
[26] On-demand single-electron source via single-cycle acoustic pulses
S. Ota u. a.
1. Dezember 2023.
[27] MoSi superconducting nanowire single-photon detectors on GaAs for on-chip integration
M. Erbe u. a.
1. Dezember 2023.
[28] Electrical resistance associated with the scattering of optically oriented electrons in n-GaAs
M. D. Ragoza u. a.
2023.
[29] Enhanced electron-spin coherence in a GaAs quantum emitter
G. N. Nguyen u. a.
Physical review letters, Bd. 131, Nr. 21, Nov. 2023
[30] Ultra-bright source of coherent single photons
A. Javadi u. a.
in 2023 IEEE Photonics Conference (IPC), Orlando, Dez. 2023
[31] Quantum interference of identical photons from remote GaAs quantum dots
A. Javadi u. a.
in 2023 IEEE Photonics Conference (IPC), Orlando, Dez. 2023
[32] A quantum dot coupled to a suspended-beam mechanical resonator: from the unresolved- to the resolved-sideband regime
C. Spinnler u. a.
9. November 2023.
[33] A single-photon emitter coupled to a phononic-crystal resonator in the resolved-sideband regime
C. Spinnler u. a.
9. November 2023.
[34] Electrical characterization of cu-doped PEDOT: PSS polymeric thin films
A. Mikaeeli u. a.
in Engineering proceedings, online, Nov. 2023, Bd. 56, Nr. 1
[35] Deterministic photon source of genuine three-qubit entanglement
Y. Meng u. a.
18. Oktober 2023.
[36] Making every photon count: a quantum polyspectra approach to the dynamics of blinking quantum emitters at low photon rates without binning
M. Sifft u. a.
16. Oktober 2023.
[37] Wavelength-tunable high-fidelity entangled photon sources enabled by dual Stark effects
C. Chen u. a.
9. August 2023.
[38] A unipolar quantum dot diode structure for advanced quantum light sources
T. Strobel u. a.
Nano letters, Bd. 23, Nr. 14, S. 6574–6580, Juli 2023
[39] Novel unipolar quantum dot diode structures for advanced sources of quantum light
S. L. Portalupi u. a.
in Conference on Lasers and Electro-Optics/Europe (CLEO/Europe 2023) and European Quantum Electronics Conference (EQEC 2023), München, 2023
[40] Violation of bell inequality by photon scattering on a two-level emitter
S. Liu u. a.
22. Juni 2023.
[41] Direct observation of non-linear optical phase shift induced by a single quantum emitter in a waveguide
M. J. R. Staunstrup u. a.
11. Mai 2023.
[42] Controlled coherent coupling in a quantum dot molecule revealed by ultrafast four-wave mixing spectroscopy
D. Wigger u. a.
ACS photonics / American Chemical Society, Bd. 10, Nr. 5, S. 1504–1511, Mai 2023
[43] Quantum-dot single-photon sources processed on silicon-nitride integrated circuits
C. F. D. Faurby u. a.
in 2023 Conference on Lasers and Electro-Optics (CLEO), San Jose, 2023
[44] Processing single-photons from a quantum dot using high-speed integrated photonic circuits on the thin film lithium-niobate-on-insulator platform
P. I. Sund u. a.
in 2023 Conference on Lasers and Electro-Optics (CLEO), San Jose, 2023.
[45] A chiral one-dimensional atom using a quantum dot in an open microcavity
A. Javadi u. a.
in 2023 Conference on Lasers and Electro-Optics (CLEO), San Jose, 2023.
[46] Super- and subradiant quantum dynamics between pairs of solid-state optical emitters
V. Angelopoulou u. a.
in 2023 Conference on Lasers and Electro-Optics (CLEO), San Jose, 2023.
[47] Semiconductor membranes for electrostatic exciton trapping in optically addressable quantum transport devices
T. Descamps u. a.
Physical review applied, Bd. 19, Nr. 4, Apr. 2023
[48] Coherent driving of direct and indirect excitons in a quantum dot molecule
F. Bopp u. a.
Physical review B, Bd. 107, Nr. 16, Apr. 2023
[49] Post-processing of real-time quantum event measurements for an optimal bandwidth
J. Kerski u. a.
Scientific reports, Bd. 13, Nr. 1, Jan. 2023
[50] Polarization-independent enhancement of optical absorption in a GaAs quantum well embedded in an air-bridge bull’s-eye cavity with metal electrodes
S. Ji u. a.
Japanese journal of applied physics, Bd. 62, Nr. SC, Jan. 2023
[51] In situ epitaxial aluminium gates in ultra-shallow GaAs/AlxGa1-xAs heterostructures for low noise quantum point contacts
Y. Ashlea Alava u. a.
in Bulletin of the American Physical Society, Las Vegas, 2023, Bd. 68, Nr. 3
[52] Direct observation of dynamics of photonic bound states
A. Javadi u. a.
in Bulletin of the American Physical Society, Las Vegas, 2023, Bd. 68, Nr. 3
[53] Charge control in a 2x2 semiconductor quantum-dot array with shared control electrodes
E. Chanrion u. a.
in Bulletin of the American Physical Society, Las Vegas, 2023, Bd. 68, Nr. 3
[54] Electrostatic coupling of double layer self assembled quantum dots
L. Berg, L. M. Schnorr, T. Heinzel, A. Ludwig, und A. Wieck
in Bulletin of the American Physical Society, Las Vegas, 2023, Bd. 68, Nr. 3
[55] Measurement of the efficiency of a bright quantum-dot-based single-photon source
N. O. Antoniadis u. a.
in Quantum Computing, Communication, and Simulation III, San Francisco, 2023, Bd. 12446
[56] A Chiral One-dimensional Atom Using a Quantum Dot in an Open Microcavity
A. Javadi u. a.
in 2023 Conference on Lasers and Electro-Optics, CLEO 2023, Jan. 2023.
[57] Quantum-Dot Single-Photon Sources Processed on Silicon-Nitride Integrated Circuits
C. F. D. Faurby u. a.
in 2023 Conference on Lasers and Electro-Optics, CLEO 2023, Jan. 2023.
[58] Super- and subradiant quantum dynamics between pairs of solid-state optical emitters
V. Angelopoulou u. a.
in 2023 Conference on Lasers and Electro-Optics, CLEO 2023, Jan. 2023.
[59] Direct observation of dynamics of photonic bound states
A. Javadi u. a.
in 2023 Conference on Lasers and Electro-Optics, CLEO 2023, Jan. 2023.
[60] Processing single-photons from a quantum dot using high-speed integrated photonic circuits on the thin film lithium-niobate-on-insulator platform
P. I. Sund u. a.
in 2023 Conference on Lasers and Electro-Optics, CLEO 2023, Jan. 2023.
[61] Novel Unipolar Quantum Dot Diode Structures for Advanced Sources of Quantum Light
S. L. Portalupi u. a.
in 2023 Conference on Lasers and Electro-Optics Europe & European Quantum Electronics Conference (CLEO/Europe-EQEC), Juni 2023, S. 0101
[62] Single electron spin dynamics in a two-electron double quantum dot under a nonequilibrium phonon environment
K. Kuroyama u. a.
in International Conference on Metamaterials, Photonic Crystals and Plasmonics, Jan. 2023, S. 886887.
[63] Quantum interference of identical photons from remote GaAs quantum dots
A. Javadi u. a.
in Photonics for Quantum 2023, Juli 2023, S. 40
[64] Elektrische Spin-Injektion in kantenemittierenden Halbleiterlasern
N. Jung u. a.
in MikroSystemTechnik Kongress 2023, Dresden, Okt. 2023, S. 108–112.
[65] Processing single-photons from a quantum dot using high-speed integrated photonic circuits on the thin film lithium-niobate-on-insulator platform
P. I. Sund u. a.
in 2023 Conference on Lasers and Electro-Optics (CLEO), San Jose, Jan. 2023
[66] Super- and subradiant quantum dynamics between pairs of solid-state optical emitters
V. Angelopoulou u. a.
in CLEO 2023, San Jose, Jan. 2023, S. FM2A.5
[67] A Chiral One-dimensional Atom Using a Quantum Dot in an Open Microcavity
A. Javadi u. a.
in CLEO 2023, San Jose, Jan. 2023, S. FF3G.7
[68] Direct observation of dynamics of photonic bound states
A. Javadi u. a.
in CLEO 2023, San Jose, Jan. 2023, S. FTh5B.1
[69] Novel unipolar quantum dot diode structures for advanced sources of quantum light
S. L. Portalupi u. a.
in European Quantum Electronics Conference, EQEC 2023 in Proceedings Conference on Lasers and Electro-Optics/Europe, CLEO/Europe 2023 and European Quantum Electronics Conference EQEC 2023, Part of Conference on Lasers and Electro-Optics/Europe, CLEO/Europe 2023 and European Quantum Electroni, Jan. 2023.
2022
[1] On-demand source of dual-rail photon pairs based on chiral interaction in a nanophotonic waveguide
F. T. Pedersen u. a.
2022.
[2] Dynamical photon-photon interaction mediated by a quantum emitter
H. Le Jeannic u. a.
18. Januar 2022.
[3] Coulomb blockade: Toward charge control of self-assembled GaN quantum dots at room temperature
C. A. Sgroi u. a.
Applied physics letters, Bd. 120, Nr. 1, Jan. 2022
[4] A chiral one-dimensional atom using a quantum dot in an open microcavity
N. O. Antoniadis u. a.
npj Quantum information, Bd. 8, Nr. 1, März 2022
[5] Wafer-scale epitaxial modulation of quantum dot density
N. Bart u. a.
Nature communications, Bd. 13, Nr. 1, März 2022
[6] Electron g-factor determined for quantum dot circuit fabricated from (110)-oriented GaAs quantum well
T. Nakagawa u. a.
Journal of applied physics, Bd. 131, Nr. 13, Apr. 2022
[7] Extending the time of coherent optical response in ensemble of singly-charged InGaAs quantum dots
A. Kosarev u. a.
Communications Physics, Bd. 5, Nr. 1, 2022
[8] In-flight detection of few electrons using a singlet-triplet spin qubit
V. Thiney u. a.
Physical review research, Bd. 4, Nr. 4, Nov. 2022
[9] Publisher Correction: Dynamical photon-photon interaction mediated by a quantum emitter
H. Le Jeannic u. a.
Nature physics, Bd. 18, Nr. 11, S. 1379, Okt. 2022
[10] Dynamical photon-photon interaction mediated by a quantum emitter
H. Le Jeannic u. a.
Nature physics, Bd. 18, Nr. 10, S. 1191–1195, Sep. 2022
[11] Generation of a single-cycle acoustic pulse: a scalable solution for transport in single-electron circuits
J. Wang u. a.
Physical review X, Bd. 12, Nr. 3, Sep. 2022
[12] Real-time observation of charge-spin cooperative dynamics driven by a nonequilibrium phonon environment
K. Kuroyama u. a.
Physical review letters, Bd. 129, Nr. 9, Aug. 2022
[13] Controlled quantum dot array segmentation via highly tunable interdot tunnel coupling
M. Nurizzo u. a.
Applied physics letters, Bd. 121, Nr. 8, Aug. 2022
[14] The role of momentum conservation on the tunneling between a two-dimensional electron gas and self-assembled quantum dots
D. Zhou u. a.
Journal of applied physics, Bd. 132, Nr. 6, Aug. 2022
[15] On-demand source of dual-rail photon pairs based on chiral interaction in a nanophotonic waveguide
F. T. Østfeldt u. a.
PRX quantum, Bd. 3, Nr. 2, Juni 2022
[16] Entangling a hole spin with a time-bin photon : a waveguide approach for quantum dot sources of multiphoton entanglement
M. H. Appel u. a.
Physical review letters, Bd. 128, Nr. 23, Juni 2022
[17] Quantum interference of identical photons from remote GaAs quantum dots
L. Zhai u. a.
Nature nanotechnology, Bd. 17, Nr. 8, S. 829–833, Mai 2022
[18] On-chip spin-photon entanglement based on single-photon scattering
M. L. Chan u. a.
16. Juni 2022.
[19] A deterministic source of single photons
P. Lodahl, A. Ludwig, und R. J. Warburton
Physics today, Bd. 75, Nr. 3, S. 44–50, März 2022
[20] A pure and indistinguishable single‐photon source at telecommunication wavelength
B. Da Lio u. a.
Advanced quantum technologies, Bd. 5, Nr. 5, März 2022
[21] Extending the time of coherent optical response in ensemble of singly-charged InGaAs quantum dots
A. Kosarev u. a.
2022.
[22] Full wafer property control of local droplet etched GaAs quantum dots
H.-G. Babin, N. Bart, M. Schmidt, N. Spitzer, A. Wieck, und A. Ludwig
Journal of crystal growth, Bd. 591, Mai 2022
[23] Integration of GaAs waveguides on a silicon substrate for quantum photonic circuits
A. Shadmani u. a.
Optics express, Bd. 30, Nr. 21, S. 37595–37602, Sep. 2022
[24] Quantum dot molecule devices with optical control of charge status and electronic control of coupling
F. Bopp u. a.
Advanced quantum technologies, Bd. 5, Nr. 10, Aug. 2022
[25] A pure and indistinguishable single-photon source at telecommunication wavelength
B. Da Lio u. a.
7. Januar 2022.
[26] Cavity-enhanced single-shot readout of a quantum dot spin within 3 nanoseconds
N. O. Antoniadis u. a.
25. Oktober 2022.
[27] Coherent control of a high-orbital hole in a semiconductor quantum dot with near-unity fidelity
J.-Y. Yan u. a.
2022.
[28] Collective super- and subradiant dynamics between distant optical quantum emitters
A. Tiranov u. a.
2022.
[29] Complete readout of two-electron spin states in a double quantum dot
M. Nurizzo u. a.
1. September 2022.
[30] Controlled quantum dot array segmentation via a highly tunable interdot tunnel coupling
M. Nurizzo u. a.
19. Juli 2022.
[31] Coulomb-mediated antibunching of an electron pair surfing on sound
J. Wang u. a.
7. Oktober 2022.
[32] Direct observation of photon bound states using a single artificial atom
N. Tomm u. a.
6. Mai 2022.
[33] Generation of a single-cycle acoustic pulse: a scalable solution for transport in single-electron circuits
J. Wang u. a.
31. Juli 2022.
[34] High-speed thin-film lithium niobate quantum processor driven by a solid-state quantum emitter
P. I. Sund u. a.
10. November 2022.
[35] In-flight detection of few electrons using a singlet-triplet spin qubit
V. Thiney u. a.
17. Oktober 2022.
[36] Independent operation of two waveguide-integrated single-photon sources
C. Papon u. a.
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[42] Lifetimes and quantum efficiencies of quantum dots deterministically positioned in photonic-crystal waveguides
X.-L. Chu u. a.
19. September 2019.
[43] Microscopic model of stacking-fault potential and exciton wave function in GaAs
M. V. Durnev u. a.
1. November 2019.
[44] Observation of the kondo screening cloud of micron lengths
I. V. Borzenets u. a.
21. Juni 2019.
[45] On-chip nanomechanical filtering of quantum-dot single-photon sources
X. Zhou u. a.
13. Oktober 2019.
[46] Quantum nondemolition measurement of an electron spin qubit
T. Nakajima u. a.
25. April 2019.
[47] Radiative auger process in the single photon limit on a quantum dot
M. C. Löbl u. a.
26. November 2019.
[48] Real-time detection of every Auger recombination in a self-assembled quantum dot
P. Lochner u. a.
12. November 2019.
[49] Suspended epoxy polymer inverted tapers for scalable fibre-coupled single-photon devices
A. D. Uğurlu u. a.
in Optics InfoBase Conference Papers, 2019
[50] Suspended spot-size converters for scalable single-photon devices
A. D. Ugurlu u. a.
21. Juni 2019.
[51] On-chip nano-electro-mechanical switching of deterministic single photons
X. Zhou u. a.
in 2019 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO), Jan. 2019.
2018
[1] A fast quantum interface between different spin qubit encodings
A. Noiri u. a.
Nature communications, Bd. 9, Nr. 1, S. 1–7, Nov. 2018
[2] Self-organized growth of quantum dots and quantum wires by combination of focused ion beams and molecular beam epitaxy
S. Scholz, R. Schott, M. Schmidt, M. Mehta, A. Ludwig, und A. Wieck
Physica status solidi B, Bd. 256, Nr. 7, Nov. 2018
[3] Tuning methods for semiconductor spin qubits
T. Botzem u. a.
Physical review applied, Bd. 10, Nr. 5, Nov. 2018
[4] Corrigendum to ‚Simultaneous measurement of thermal conductivity and diffusivity of an undoped Al0.33Ga0.67As thin film epitaxially grown on a heavily Zn doped GaAs using spectrally-resolved modulated photothermal infrared radiometry‘, [Thermochim. Acta 662 (2018), 69-74]
M. Pawlak, S. Pal, S. Scholz, A. Ludwig, und A. Wieck
Thermochimica acta, Bd. 669, S. 194, Nov. 2018
[5] Laplace deep level transient spectroscopy on self-assembled quantum dots
L. Schnorr, T. M. Heinzel, S. Scholz, A. Ludwig, und A. Wieck
Journal of applied physics, Bd. 124, Nr. 10, S. 1–9, Sep. 2018
[6] Four single-spin Rabi oscillations in a quadruple quantum dot
T. Ito u. a.
Applied physics letters, Bd. 113, Nr. 9, S. 1–6, Aug. 2018
[7] Unveiling the bosonic nature of an ultrashort few-electron pulse
G. Roussely u. a.
Nature communications, Bd. 9, Nr. 1, S. 1–6, Juli 2018
[8] Simultaneous measurement of infrared absorption coefficient of Carbon doped Al0.33Ga0.67As thin film and thermal boundary resistance between thin film and heavily Zn doped GaAs substrate using spectrally-resolved modulated photothermal infrared radiometry
M. Pawlak, N. Horny, S. Scholz, C. Ebler, A. Ludwig, und A. Wieck
Thermochimica acta, Bd. 667, S. 73–78, Juni 2018
[9] Coherent transfer of electron spin correlations assisted by dephasing noise
T. Nakajima u. a.
Nature communications, Bd. 9, Nr. 1, S. 1–29, Mai 2018
[10] Spin–photon interface and spin-controlled photon switching in a nanobeam waveguide
A. Javadi u. a.
Nature nanotechnology, Bd. 13, Nr. 5, S. 398–403, Apr. 2018
[11] Quantum optics with near-lifetime-limited quantum-dot transitions in a nanophotonic waveguide
H. Thyrrestrup u. a.
Nano letters, Bd. 18, Nr. 3, S. 1801–1806, März 2018
[12] Simultaneous measurement of thermal conductivity and diffusivity of an undoped Al 0.33 Ga 0.67 As thin film epitaxially grown on a heavily Zn doped GaAs using spectrally-resolved modulated photothermal infrared radiometry
M. Pawlak, S. Pal, S. Scholz, A. Ludwig, und A. Wieck
Thermochimica acta, Bd. 662, S. 69–74, Feb. 2018
[13] Coherent optical control of a quantum-dot spin-qubit in a waveguide-based spin-photon interface
D. Ding u. a.
14. Oktober 2018.
[14] Coherent manipulation of a single electron surfing on a sound wave
S. Takada, H. Edlbauer, A. Ludwig, A. Wieck, T. Meunier, und C. Bäuerle
2018.
[15] Measuring back-action of a single qubit on its nuclear spin environment through spin-echo correlations
P. Bethke u. a.
2018.
[16] Optical detection of single electron transport dynamics
A. Kurzmann u. a.
2018
[17] Spin-photon interface controlled optical switching in a nanobeam waveguide
T. Schröder u. a.
in 2018 Conference on Lasers and Electro-Optics (CLEO), San Jose, Calif., 2018
[18] Universal ratio of Coulomb interaction to geometric quantization in (In, Ga)As/GaAs quantum dots
M. Bayer, A. Ludwig, und A. Wieck
Physics of the solid state, Bd. 60, Nr. 8, S. 1629–1634, 2018
[19] Quantum state transfer of angular momentum via single electron photo-excitation from a Zeeman-resolved light hole
K. Kuroyama u. a.
14. Mai 2018.
[20] Overcoming Ehrlich-Schwöbel barrier in (1 1 1)A GaAs molecular beam epitaxy
J. Ritzmann, R. Schott, K. Gross, D. Reuter, A. Ludwig, und A. Wieck
Journal of crystal growth, Bd. 481, S. 7–10, 2018
[21] Dephasing of InAs quantum dot p-shell excitons studied using two-dimensional coherent spectroscopy
T. Suzuki u. a.
Physical review B, Bd. 98, Nr. 19, Nov. 2018
[22] Detuning dependence of Rabi oscillations in an InAs self-assembled quantum dot ensemble
T. Suzuki, R. Singh, M. Bayer, A. Ludwig, A. Wieck, und S. T. Cundiff
Physical review B, Bd. 97, Nr. 16, Apr. 2018
[23] Illumination-induced nonequilibrium charge states in self-assembled quantum dots
S. Valentin u. a.
Physical review B, Bd. 97, Nr. 4, Jan. 2018
[24] Difference in charge and spin dynamics in a quantum dot-lead coupled system
T. Otsuka u. a.
15. August 2018.
[25] Far-field nanoscopy on a semiconductor quantum dot via a rapid-adiabatic-passage-based switch
T. Kaldewey, A. V. Kuhlmann, S. Valentin, A. Ludwig, A. Wieck, und R. J. Warburton
Nature photonics, Bd. 12, Nr. 2, S. 68–72, 2018
[26] A charge-tunable quantum dot deep in the strong coupling regime of cavity QED
D. Najer u. a.
IEEE Photonics Society Summer Topicals Meeting series 2018. IEEE Computer Society Press, Piscataway, NJ, S. 169–170, 2018.
[27] Excitons in InGaAs quantum dots without electron wetting layer states
M. C. Löbl u. a.
1. Oktober 2018.
[28] Near lifetime-limited emitter in a nanophotonic waveguide
H. Thyrrestrup u. a.
in 2018 Conference on Lasers and Electro-Optics (CLEO), San Jose, Calif., 2018
[29] Coherent control of individual electron spins in a two dimensional array of quantum dots
P.-A. Mortemousque u. a.
19. August 2018.
[30] Nanomechanical single-photon routing
C. Papon u. a.
27. November 2018.
[31] Coherent transfer of electron spin correlations assisted by dephasing noise
T. Nakajima u. a.
2018.
[32] Towards entanglement transfer between photon pairs to electron-photon pairs with Zeeman-resolved light hole
C.-Y. Chang u. a.
in ICIQP2018 - October 15-17, 2018, Paris, 2018
[33] Coupling a charge-tunable quantum dot to a cavity mode with cooperativity above one hundred
D. Najer u. a.
in ICIQP2018 - October 15-17, 2018, Paris, 2018
[34] Spin-Photon Interface Controlled Optical Switching in a Nanobeam Waveguide
T. Schroder u. a.
in 2018 Conference on Lasers and Electro-Optics, CLEO 2018 - Proceedings, 2018
[35] A fast quantum interface between different spin qubit encodings
A. Noiri u. a.
13. April 2018.
[36] A gated quantum dot far in the strong-coupling regime of cavity-QED at optical frequencies
D. Najer u. a.
20. Dezember 2018.
[37] Dephasing of InAs quantum dot p-shell excitons using two-dimensional coherent spectroscopy
T. Suzuki u. a.
22. August 2018.
[38] Four single-spin Rabi oscillations in a quadruple quantum dot
T. Ito u. a.
16. Mai 2018.
[39] Optical detection of single-electron tunneling into a semiconductor quantum dot
A. Kurzmann u. a.
18. Dezember 2018.
[40] Photon noise suppression by a built-in feedback loop
A. Al-Ashouri u. a.
17. Juli 2018.
[41] Tuning methods for semiconductor spin–qubits
T. Botzem u. a.
11. Januar 2018.
[42] Near lifetime-limited emitter in a nanophotonic waveguide
H. Thyrrestrup u. a.
in 2018 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO), Jan. 2018.
[43] Spin-Photon Interface Controlled Optical Switching in a Nanobeam Waveguide
T. Schroder u. a.
in 2018 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO), Jan. 2018.
2017
[1] Electro-optic routing of photons from a single quantum dot in photonic integrated circuits
L. Midolo u. a.
Optics express, Bd. 25, Nr. 26, S. 1–17, Dez. 2017
[2] Erratum:
M. Pawlak, S. Pal, A. Ludwig, und A. Wieck
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[3] Single electron-photon pair creation from a single polarization-entangled photon pair
K. Kuroyama u. a.
Scientific reports, Bd. 7, Nr. 1, S. 1–8, Nov. 2017
[4] Non-universal transmission phase behaviour of a large quantum dot
H. Edlbauer u. a.
Nature communications, Bd. 8, Nr. 1, Nov. 2017
[5] Narrow optical linewidths and spin pumping on charge-tunable close-to-surface self-assembled quantum dots in an ultrathin diode
M. C. Löbl u. a.
Physical review B, Bd. 96, Nr. 16, Okt. 2017
[6] Indistinguishable and efficient single photons from a quantum dot in a planar nanobeam waveguide
G. Kiršanskė u. a.
Physical review B, Bd. 96, Nr. 16, Okt. 2017
[7] On the infrared absorption coefficient measurement of thick heavily Zn doped GaAs using spectrally resolved modulated photothermal infrared radiometry
M. Pawlak, S. Pal, A. Ludwig, und A. Wieck
Journal of applied physics, Bd. 122, Nr. 13, S. 1–35, Okt. 2017
[8] Higher-order spin and charge dynamics in a quantum dot-lead hybrid system
T. Otsuka u. a.
Scientific reports, Bd. 7, Nr. 1, S. 1–7, Sep. 2017
[9] Coherent long-distance displacement of individual electron spins
H. Flentje u. a.
Nature communications, Bd. 8, Nr. 1, Sep. 2017
[10] Robust single-shot spin measurement with 99.5% fidelity in a quantum dot array
T. Nakajima u. a.
Physical review letters, Bd. 119, Nr. 1, Juli 2017
[11] Positive centre voltage in T-branch junctions on n-type GaAs/AlGaAs based on hydrodynamics
M. Szelong, A. Ludwig, A. Wieck, und U. Kunze
Semiconductor science and technology, Bd. 32, Nr. 10, S. 1–7, Juli 2017
[12] Demonstrating the decoupling regime of the electron-phonon interaction in a quantum dot using chirped optical excitation
T. Kaldewey u. a.
Physical review B, Bd. 95, Nr. 24, Juni 2017
[13] Quantum confinement in high electron mobility transistors
S. Pal, S. Valentin, A. Ludwig, und A. Wieck
in Different types of field-effect transistors, M. Pejović und M. M. Pejovic, Hrsg. s. l.: IntechOpen, 2017, S. 64–88.
[14] Mesoscopic phase behavior in a quantum dot around crossover between single-level and multilevel transport regimes
S. Takada, M. Yamamoto, C. Bäuerle, A. Ludwig, A. Wieck, und S. Z. Tarucha
Physical review B, Bd. 95, Nr. 24, Juni 2017
[15] A linear triple quantum dot system in isolated configuration
H. Flentje u. a.
Applied physics letters, Bd. 110, Nr. 23, S. 1–5, Juni 2017
[16] A triangular triple quantum dot with tunable tunnel couplings
A. Noiri u. a.
Semiconductor science and technology, Bd. 32, Nr. 8, S. 1–6, Mai 2017
[17] Ultra-low charge and spin noise in self-assembled quantum dots
A. Ludwig u. a.
Journal of crystal growth, Bd. 477, S. 193–196, Nov. 2017
[18] Focused ion beam supported growth of monocrystalline wurtzite InAs nanowires grown by molecular beam epitaxy
S. Scholz u. a.
Journal of crystal growth, Bd. 470, S. 46–50, Apr. 2017
[19] Coherent and robust high-fidelity generation of a biexciton in a quantum dot by rapid adiabatic passage
T. Kaldewey u. a.
Physical review B, Bd. 95, Nr. 16, Apr. 2017
[20] Ion-induced interdiffusion of surface GaN quantum dots
C. Rothfuchs u. a.
Nuclear instruments & methods in physics research B, Bd. 409, S. 107–110, 2017
[21] Conversion from single photon to single electron spin using electrically controllable quantum dots
A. Oiwa u. a.
Journal of the Physical Society of Japan, Bd. 86, Nr. 1, S. 1–10, 2017
[22] Optical nanoscopy via quantum control
T. Kaldewey, A. V. Kuhlmann, S. Valentin, A. Ludwig, A. Wieck, und R. J. Warburton
6. Januar 2017.
[23] On measurement of the thermal diffusivity of moderate and heavily doped semiconductor samples using modulated photothermal infrared radiometry
M. Pawlak, A. Panas, A. Ludwig, und A. Wieck
Thermochimica acta, Bd. 650, S. 33–38, 2017
[24] Classical information transfer between distant quantum dots using individual electrons in fast moving quantum dots
S. Hermelin u. a.
Physica status solidi B, Bd. 254, Nr. 3, S. 1–12, 2017
[25] Electron dynamics in transport and optical measurements of self-assembled quantum dots
A. Kurzmann u. a.
Physica status solidi B, Bd. 254, Nr. 3, S. 1–13, 2017
[26] All-electrical measurement of the triplet-singlet spin relaxation time in self-assembled quantum dots
K. Eltrudis u. a.
Applied physics letters, Bd. 111, Nr. 9, S. 1–4, 2017
[27] New amidinate complexes of indium(III): promising CVD precursors for transparent and conductive In2O3 thin films
M. Gebhard u. a.
Dalton transactions, Bd. 46, Nr. 31, S. 10220–10231, 2017
[28] Efficiency enhancement of the coherent electron spin-flip Raman scattering through thermal phonons in (In,Ga)As/GaAs quantum dots
J. Debus u. a.
Physical review B, Bd. 95, Nr. 20, Mai 2017
[29] Optical visualization of radiative recombination at partial dislocations in GaAs
T. Karin, X. Y. Linpeng, A. K. Rai, A. Ludwig, A. Wieck, und K. M. C. Fu
in Get energized with solar power, Washington, DC, 2017
[30] Synthesis and evaluation of new copper ketoiminate precursors for a facile and additive-free solution-based approach to nanoscale copper oxide thin films
S. Karle u. a.
Dalton transactions, Bd. 46, Nr. 8, S. 2670–2679, 2017
[31] A single eletron-photon pair generation from a single polarization-entangled photon pair
K. Kuroyama u. a.
15. März 2017.
[32] Robust single-shot spin measurement with 99.5% fidelity in a quantum dot array
T. Nakajima u. a.
2017.
[33] Unveiling the bosonic nature of an ultrashort few-electron pulse
G. Roussely u. a.
11. September 2017.
[34] Thermal and infrared characterization of AlGaAs thin film epitaxially grown on Zn doped GaAs using spectrally resolved modulated photothermal infrared radiometry
M. Pawlak, S. Pal, A. Ludwig, M. Kwiatek, J. Pelzl, und A. Wieck
in Book of abstracts, 19th International Conference on Photoacoustic and Photothermal Phenomena, Bilbao, 2017, S. 81
[35] A linear triple quantum dot system in isolated configuration
H. Flentje u. a.
19. Mai 2017.
[36] A single electron-photon pair generation from a single polarization-entangled photon pair
K. Kuroyama u. a.
15. März 2017.
[37] A triangular triple quantum dot with tunable tunnel couplings
A. Noiri u. a.
29. Mai 2017.
[38] Coherent and robust high-fidelity generation of a biexciton in a quantum dot by rapid adiabatic passage
T. Kaldewey u. a.
5. Januar 2017.
[39] Coherent long-distance displacement of individual electron spins
H. Flentje u. a.
5. Januar 2017.
[40] Demonstrating the decoupling regime of the electron-phonon interaction in a quantum dot using chirped optical excitation
T. Kaldewey u. a.
5. Januar 2017.
[41] Electro-optic routing of photons from single quantum dots in photonic integrated circuits
L. Midolo u. a.
20. Juli 2017.
[42] Illumination-induced nonequilibrium charge states in self-assembled quantum dots
S. Valentin u. a.
14. Dezember 2017.
[43] Indistinguishable and efficient single photons from a quantum dot in a planar nanobeam waveguide
G. Kiršanske u. a.
2017.
[44] Mesoscopic phase behavior in a quantum dot around crossover between single-level and multi-level transport regimes
S. Takada, M. Yamamoto, C. Bäuerle, A. Ludwig, A. Wieck, und S. Z. Tarucha
26. September 2017.
[45] Narrow optical linewidths and spin pumping on charge-tunable, close-to-surface self-assembled quantum dots in an ultra-thin diode
M. C. Löbl u. a.
1. August 2017.
[46] Non-universal transmission phase behaviour of a large quantum dot
H. Edlbauery u. a.
26. September 2017.
[47] Quantum optics with near lifetime-limited quantum-dot transitions in a nanophotonic waveguide
H. Thyrrestrup u. a.
2017.
[48] Spin-photon interface and spin-controlled photon switching in a nanobeam waveguide
A. Javadi u. a.
19. September 2017.
2016
[1] Thermal shift of the resonance between an electron gas and quantum dots: what is the origin?
F. Brinks, A. Wieck, und A. Ludwig
New journal of physics, Bd. 18, Nr. 12, Dez. 2016
[2] Probing indirect exciton complexes in a quantum dot molecule via capacitance-voltage spectroscopy
S. Pal u. a.
Physical review B, Bd. 94, Nr. 24, Dez. 2016
[3] Decoupling a hole spin qubit from the nuclear spins
J. H. Prechtel u. a.
Nature materials, Bd. 15, Nr. 9, S. 981–986, 2016
[4] Coherent evolution of inhomogeneous exciton/biexciton system in an InAs quantum dot ensemble
T. Suzuki, R. Singh, M. Bayer, A. Ludwig, A. Wieck, und S. T. Cundiff
in CLEO: QELS_Fundamental Science, San Jose, Calif, 2016, S. FW1N.3
[5] Altering the luminescence properties of self-assembled quantum dots in GaAs by focused ion beam implantation
C. Rothfuchs, N. Kukharchyk, M. Greff, A. Wieck, und A. Ludwig
Applied physics B, Bd. 122, Nr. 3, S. 1–6, 2016
[6] Coherent electron-spin-resonance manipulation of three individual spins in a triple quantum dot
A. Noiri u. a.
Applied physics letters, Bd. 108, Nr. 15, S. 1–5, 2016
[7] Injection of a single electron from static to moving quantum dots
B. Bertrand u. a.
Nanotechnology, Bd. 27, Nr. 21, S. 1–5, 2016
[8] Coherent control of the exciton-biexciton system in an InAs self-assembled quantum dot ensemble
T. Suzuki, R. Singh, M. Bayer, A. Ludwig, A. Wieck, und S. T. Cundiff
Physical review letters, Bd. 117, Nr. 15, Okt. 2016
[9] Spatially indirect transitions in electric field tunable quantum dot diodes
A. K. Rai, S. Gordon, A. Ludwig, A. Wieck, A. Zrenner, und D. Reuter
Physica status solidi B, Bd. 253, Nr. 3, S. 437–441, 2016
[10] Optical visualization of radiative recombination at partial dislocations in GaAs
T. Karin, X. Linpeng, A. K. Rai, A. Ludwig, A. Wieck, und K.-M. C. Fu
in 2016 IEEE 43rd Photovoltaic Specialists Conference (PVSC), Portland, Or., 2016, S. 1989–1992
[11] Stacking faults as a novel 2D potential for excitons
T. Karin u. a.
in CLEO: QELS_Fundamental Science, San Jose, Calif, 2016, S. FW1N.2
[12] Auger recombination in self-assembled quantum dots: quenching and broadening of the charged exciton transition
A. Kurzmann, A. Ludwig, A. Wieck, A. Lorke, und M. Geller
Nano letters, Bd. 16, Nr. 5, S. 3367–3372, 2016
[13] Fast spin information transfer between distant quantum dots using individual electrons
B. Bertrand u. a.
Nature nanotechnology, Bd. 11, Nr. 8, S. 672–676, 2016
[14] Role of the electron spin in determining the coherence of the nuclear spins in a quantum dot
G. Wüst u. a.
Nature nanotechnology, Bd. 11, Nr. 10, S. 885–889, 2016
[15] Modifying the spectral emission of a terahertz quantum cascade laser with double pulse injection seeding
S. Markmann u. a.
in CLEO: QELS_Fundamental Science, San Jose, Calif, 2016
[16] Low-temperature behavior of transmission phase shift across a Kondo correlated quantum dot
S. Takada u. a.
Physical review B, Bd. 94, Nr. 8, Aug. 2016
[17] Giant permanent dipole moment of two-dimensional excitons bound to a single stacking fault
T. Karin u. a.
Physical review B, Bd. 94, Nr. 4, Juli 2016
[18] Nanoscale nonlinear effects in erbium-implanted yttrium orthosilicate
N. Kukharchyk u. a.
Journal of luminescence, Bd. 177, S. 266–274, 2016
[19] Photoelectron generation and capture in the resonance fluorescence of a quantum dot
A. Kurzmann, A. Ludwig, A. Wieck, A. Lorke, und M. Geller
Applied physics letters, Bd. 108, Nr. 26, S. 1–4, 2016
[20] Photoluminescence of gallium ion irradiated hexagonal and cubic GaN quantum dots
C. Rothfuchs u. a.
Nuclear instruments & methods in physics research B, Bd. 383, S. 1–5, 2016
[21] Optical blocking of electron tunneling into a single self-assembled quantum dot
A. Kurzmann u. a.
Physical review letters, Bd. 117, Nr. 1, Juni 2016
[22] Signatures of hyperfine, spin-orbit, and decoherence effects in a Pauli spin blockade
T. Fujita u. a.
Physical review letters, Bd. 117, Nr. 20, Nov. 2016
[23] Quantum dephasing in a gated GaAs triple quantum dot due to nonergodic noise
M. R. Delbecq u. a.
Physical review letters, Bd. 116, Nr. 4, Jan. 2016
[24] Single-electron spin resonance in a quadruple quantum dot
T. Otsuka u. a.
Scientific reports, Bd. 6, 2016
[25] Tunneling induced spin dynamics in a quantum dot-lead hybrid system
T. Otsuka u. a.
27. August 2016.
[26] Footprints of hyperfine, spin-orbit, and decoherence effects in Pauli spin blockade
T. Fujita u. a.
15. März 2016.
[27] Observation of magnetic non-reciprocity for mobile excitons bound to stacking-fault potentials
K.-M. Fu, K. Todd, X. Linpeng, A. Ludwig, A. Wieck, und M. Glazov
in Bulletin of the American Physical Society, Baltimore, MD, 2016, Bd. 61, Nr. 2
[28] Giant permanent dipole moment of 2D excitons bound to a single stacking fault
K. Todd u. a.
2016.
[29] GaAs横型量子ドットにおける光学的スピン閉塞効果を用いた量子状態転写の実証
K. Kuroyama u. a.
Nihon-Butsuri-Gakkai-kōen-gaiyōshū, Bd. 71, Nr. 2(0), S. 1157, 2016.
[30] Quantum dephasing of spin qubits due to nonergodic noise
M. R. Delbecq u. a.
Aug. 2016.
[31] Stacking faults as a novel 2D potential for excitons
K.-M. C. Fu u. a.
in 2016 Conference on Lasers and Electro-Optics, CLEO 2016, 2016
[32] Modifying the spectral emission of a terahertz quantum cascade laser with double pulse injection seeding
S. Markmann u. a.
in Optics InfoBase Conference Papers, 2016
[33] Stacking Faults as a Novel 2D Potential for Excitons
K.-M. C. Fu u. a.
in Optics InfoBase Conference Papers, 2016
[34] Optical Visualization of Radiative Recombination at Partial Dislocations in GaAs
T. Karin, X. Linpeng, A. K. Rail, A. Ludwig, A. Wieck, und K.-M. C. Fu
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2015
[1] Optical properties of strain-compensated CdSe/ZnSe/(Zn,Mg)Se quantum well microdisks
M. Ruth u. a.
Optics express, Bd. 23, Nr. 22, S. 29079–29088, Okt. 2015
[2] Ultrawide electrical tuning of light matter interaction in a high electron mobility transistor structure
S. Pal u. a.
Scientific reports, Bd. 5, 2015
[3] Monitoring of amorfization of the oxygen implanted layers in silicon wafers using photothermal radiometry and modulated free carrier absorption methods
M. Maliński, M. Pawlak, Ł. Chrobak, S. Pal, und A. Ludwig
Applied physics A, Bd. 118, Nr. 3, S. 1009–1014, 2015
[4] Direct photonic coupling of a semiconductor quantum dot and a trapped ion
H. M. Meyer u. a.
Physical review letters, Bd. 114, Nr. 12, März 2015
[5] Measurement of the transmission phase of an electron in a quantum two-path interferometer
S. Takada u. a.
Applied physics letters, Bd. 107, Nr. 6, S. 1–5, 2015
[6] Hybrid architecture for shallow accumulation mode AlGaAs/GaAs heterostructures with epitaxial gates
S. J. MacLeod u. a.
Applied physics letters, Bd. 106, Nr. 1, S. 1–5, 2015
[7] Single photoelectron spin detection and angular momentum transfer in a gate defined quantum dot
T. Fujita u. a.
2015
[8] Optical blocking of electron tunneling into a single self-assembled quantum dot
A. Kurzmann u. a.
2015
[9] The effect of charged quantum dots on the mobility of a two-dimensional electron gas: how important is the Coulomb scattering?
A. Kurzmann, A. Beckel, A. Ludwig, A. Wieck, A. Lorke, und M. Geller
Journal of applied physics, Bd. 117, Nr. 5, S. 1–5, 2015
[10] Epitaxial lift-off for solid-state cavity quantum electrodynamics
L. Greuter u. a.
Journal of applied physics, Bd. 118, Nr. 7, S. 1–6, 2015
[11] Tuning the tunneling probability between low-dimensional electron systems by momentum matching
D. Zhou, A. Beckel, A. Ludwig, A. Wieck, M. Geller, und A. Lorke
Applied physics letters, Bd. 106, Nr. 24, S. 1–4, 2015
[12] Strong coupling of intersubband resonance in a high electron mobility transistor structure to a THz metamaterial by ultrawide electrical tuning
S. Pal u. a.
2015
[13] Extending the spectral range of CdSe/ZnSe quantum wells by strain engineering
A. Finke u. a.
Physical review B, Bd. 91, Nr. 3, Jan. 2015
[14] Electrically tunable hole g factor of an optically active quantum dot for fast spin rotations
J. H. Prechtel u. a.
Physical review B, Bd. 91, Nr. 16, Apr. 2015
[15] Excitons bound to stacking fault planes in GaAs: a novel 2D excitonic system
T. Karin, X. Linpeng, S. Harvey, A. Ludwig, A. Wieck, und K.-M. Fu
in Bulletin of the American Physical Society, San Antonio, TX, 2015, Bd. 60, Nr. 1
[16] Quantum manipulation of two-electron spin states in isolated double quantum dots
B. Bertrand u. a.
Physical review letters, Bd. 115, Nr. 9, Aug. 2015
[17] Long-range spin transfer using individual electrons
B. Bertrand u. a.
2015
[18] Interplay of electron and nuclear spin noise in n-type GaAs
F. Berski, J. Hübner, M. Oestreich, A. Ludwig, A. Wieck, und M. Glazov
Physical review letters, Bd. 115, Nr. 17, Okt. 2015
[19] Optical and microwave properties of focused ion beam implanted erbium ions in Y2SiO5 crystals
N. Kukharchyk u. a.
in CLEO: Applications and Technology, 2015
[20] Focused ion beam induced growth of monocrystalline InAs nanowires
S. Scholz u. a.
2015
[21] Spectral modification of the laser emission of a terahertz quantum cascade laser induced by broad-band double pulse injection seeding
S. Markmann u. a.
Applied physics letters, Bd. 107, Nr. 11, S. 1–5, 2015
[22] Density-chopped far-infrared transmission spectroscopy to probe subband-landau splittings and tune intersubband transitions
S. Pal u. a.
in CLEO: Applications and Technology, 2015
[23] Transform-limited single photons from a single quantum dot
A. V. Kuhlmann u. a.
Nature communications, Bd. 6, S. 1–6, 2015
[24] Fast probe of local electronic states in nanostructures utilizing a single-lead quantum dot
T. Otsuka u. a.
Scientific reports, Bd. 5, 2015
[25] Interplay of electron and nuclear spin noise in GaAs
F. Berski, J. Hübner, M. Oestreich, A. Ludwig, A. Wieck, und M. Glazov
17. Juni 2015.
[26] Double-pulse injection seeding of a terahertz quantum cascade laser
S. Markmann u. a.
in 2015 40th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2015), Hongkong, 2015
[27] Strong coupling of intersubband resonance in a single triangular well to a THz metamaterial
S. Pal u. a.
in 2015 40th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2015), Hongkong, 2015
[28] Optical and microwave properties of focused ion beam implanted Erbium ions in Y2SiO5 crystals
N. Kukharchyk u. a.
in 2015 Conference on Lasers and Electro-Optics (CLEO 2015), San José, Calif., 2015.
[29] Density-chopped far-infrared transmission spectroscopy to probe subband-Landau splittings and tune intersubband transitions
S. Pal u. a.
in 2015 Conference on Lasers and Electro-Optics (CLEO 2015), San José, Calif., 2015.
2014
[1] Asymmetry of charge relaxation times in quantum dots: the influence of degeneracy
A. Beckel u. a.
epl, Bd. 106, Nr. 4, S. 1–7, 2014
[2] A small mode volume tunable microcavity: development and characterization
L. Greuter u. a.
Applied physics letters, Bd. 105, Nr. 12, S. 1–5, 2014
[3] Investigation of carrier scattering mechanisms in n-Cd1-xMgxSe single crystals using Fourier transform infrared spectroscopy
M. Pawlak u. a.
Infrared physics & technology, Bd. 64, S. 115–118, 2014
[4] A linear relationship between the Hall carrier concentration and the effective absorption coefficient measured by means of photothermal radiometry in IR semi-transparent n-type CdMgSe mixed crystals
M. Pawlak, M. Malinski, F. Firszt, J. Pelzl, A. Ludwig, und A. Marasek
Measurement science and technology, Bd. 25, Nr. 3, S. 035204-1-035204–9, 2014
[5] Manipulation of the nuclear spin ensemble in a quantum dot with chirped magnetic resonance pulses
M. Munsch u. a.
Nature nanotechnology, Bd. 9, Nr. 9, S. 671–675, 2014
[6] Direct quantitative electrical measurement of many-body interactions in exciton complexes in InAs quantum dots
P. A. Labud, A. Ludwig, A. Wieck, G. Bester, und D. Reuter
Physical review letters, Bd. 112, Nr. 4, Jan. 2014
[7] Transmission phase in the Kondo regime revealed in a two-path interferometer
S. Takada u. a.
Physical review letters, Bd. 113, Nr. 12, Sep. 2014
[8] Erratum: Manipulation of the nuclear spin ensemble in a quantum dot with chirped magnetic resonance pulses
M. Munsch u. a.
Nature nanotechnology, Bd. 9, Nr. 10, S. 867, 2014
[9] Photoluminescence of focused ion beam implanted Er 3+ :Y 2 SiO 5 crystals
N. Kukharchyk u. a.
Physica status solidi Rapid research letters, Bd. 8, Nr. 10, S. 880–884, Juli 2014
[10] Infrared transmission spectroscopy of charge carriers in self-assembled InAs quantum dots under surface electric fields
S. Pal u. a.
Journal of physics Condensed matter, Bd. 26, Nr. 50, S. 505801-1-505801–6, 2014
[11] Time-resolved transconductance spectroscopy on self-assembled quantum dots: spectral evolution from single-into many-particle states
A. Beckel, A. Ludwig, A. Wieck, A. Lorke, und M. Geller
Physical review B, Bd. 89, Nr. 15, Apr. 2014
[12] Single photoelectron detection after selective excitation of electron heavy-hole and electron light-hole pairs in double quantum dots
K. Morimoto u. a.
Physical review B, Bd. 90, Nr. 8, Aug. 2014
[13] Tuning the electrically evaluated electron Landé g factor in GaAs quantum dots and quantum wells of different well widths
G. Allison u. a.
Physical review B, Bd. 90, Nr. 23, Dez. 2014
[14] Realisation of a photonic link between a trapped ion and a semiconductor quantum dot
C. Le Gall u. a.
in Quantum information and measurement, 2014
[15] Transient and persistent current induced conductivity changes in GaAs/AlGaAs high-electron-mobility transistors
C. Schulte-Braucks, S. Valentin, A. Ludwig, und A. Wieck
Applied physics letters, Bd. 104, Nr. 13, S. 132104-1-132104–5, 2014
[16] Accumulation mode GaAs/AlGaAs 2D electron system with independent control of the channel and contact resistance
S. J. MacLeod u. a.
in Bulletin of the American Physical Society, Denver, Colo., 2014, Bd. 59, Nr. 1
[17] Angular momentum conversion from single photons to single electron spins in a lateral double quantum dot
A. Oiwa u. a.
in 2014 International Conference on Solid State Devices and Materials, Tsukuba, 2014, S. 808–809
[18] Annulated and bridged tetrahydrofurans from alkenoxyl radical cyclization
C. Schur, H. Kelm, T. Gottwald, A. Ludwig, R. Kneuer, und J. Hartung
Organic & biomolecular chemistry, Bd. 12, Nr. 41, S. 8288–8307, Aug. 2014
[19] Realisation of a photonic link between a trapped ion and a semiconductor quantum dot
C. L. Gall u. a.
in Conference on Lasers and Electro-Optics Europe - Technical Digest, 2014
[20] Realisation of a photonic link between a trapped ion and a semiconductor quantum dot
C. L. Gall u. a.
in Optics InfoBase Conference Papers, 2014
[21] Realisation of a photonic link between a trapped ion and a semiconductor quantum dot
C. L. Gall u. a.
in Optics InfoBase Conference Papers, 2014
[22] Realisation of a photonic link between a trapped ion and a semiconductor quantum dot
C. Le Gall u. a.
in CLEO: 2014, Juni 2014
[23] Realisation of a photonic link between a trapped ion and a semiconductor quantum dot
C. Le Gall u. a.
Jan. 2014.
[24] Frequency-stabilized source of single photons from a solid-state qubit
J. H. Prechtel u. a.
Physical review X, Bd. 3, Nr. 4, Feb. 2014
2013
[1] Frequency-stabilized source of single photons from a solid-state qubit
J. H. Prechtel u. a.
Physical review X, Bd. 3, Nr. 4, Okt. 2013
[2] Growth of InAs/InGaAs nanowires on GaAs (111) B substrates
S. Scholz, R. Schott, A. Ludwig, A. Wieck, und D. Reuter
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Regensburg, 2013, Bd. 6. Reihe, Bd 48, Nr. 3
[3] A dark-field microscope for background-free detection of resonance fluorescence from single semiconductor quantum dots operating in a set-and-forget mode
A. V. Kuhlmann u. a.
Review of scientific instruments, Bd. 84, Nr. 7, S. 73905, 2013
[4] Linewidth of single photons from a single quantum dot: key role of nuclear spins
A. V. Kuhlmann u. a.
2013
[5] Nondestructive real-time measurement of charge and spin dynamics of photoelectrons in a double quantum dot
T. Fujita u. a.
Physical review letters, Bd. 110, Nr. 26, Juni 2013
[6] Spin storage and readout in charge-tunable structures with InGaAs quantum dots
A. Merz u. a.
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Regensburg, 2013, Bd. 6. Reihe, Bd 48, Nr. 3
[7] Spin relaxation in spin light-emitting diodes: effects of magnetic field and temperature
H. Höpfner u. a.
Ultrafast phenomena and nanophotonics XVII, Bd. 8623. SPIE, Bellingham, Wash., S. 86230A–1, 2013.
[8] Spin relaxation length in quantum dot spin LEDs
H. Höpfner u. a.
Physica status solidi C, Bd. 10, Nr. 9, S. 1214–1217, 2013
[9] Spin injection, transport, and relaxation in spin light-emitting diodes: magnetic field effects
H. Höpfner u. a.
in Spintronics VI, San Diego, Calif., 2013, Bd. 8813, S. 8813–43
[10] Spin injection and spin relaxation: magnetic field effects
H. Höpfner u. a.
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Regensburg, 2013, Bd. 6. Reihe, Bd 48, Nr. 3
[11] Quantum dot spintronics: fundamentals and applications
A. Ludwig u. a.
in Magnetic nanostructures, Bd. 246, H. Zabel und M. Farle, Hrsg. Berlin: Springer, 2013, S. 235–268.
[12] High-resolution mass spectrometer for liquid metal ion sources
M. Wortmann, A. Ludwig, J. Meijer, D. Reuter, und A. Wieck
Review of scientific instruments, Bd. 84, Nr. 9, S. 93305, 2013
[13] Towards isolating a single impurity-bound hole
R. Barbour, K. Todd, K.-M. Fu, Y. Hirayama, A. Ludwig, und A. Wieck
in Bulletin of the American Physical Society, Baltimore, MD, 2013, Bd. 58, Nr. 1
[14] Charge noise and spin noise in a semiconductor quantum device
A. V. Kuhlmann u. a.
Nature physics, Bd. 9, S. 570–575, 2013
2012
[1] Electron-nuclei spin coupling in GaAs - free versus localized electrons
J. Huang, Y. S. Chen, A. Ludwig, D. Reuter, A. Wieck, und G. Bacher
Applied physics letters, Bd. 100, Nr. 13, S. 132103-1-132103–4, 2012
[2] Probing single-charge fluctuations at a GaAs/AlAs interface using laser spectroscopy on a nearby InGaAs quantum dot
J. Houel u. a.
Physical review letters, Bd. 108, Nr. 10, März 2012
[3] Room temperature spin relaxation in quantum dot based spin-optoelectronic devices
H. Höpfner u. a.
in Ultrafast phenomena and nanophotonics XVI, San Francisco, Calif., 2012, Bd. 8260, S. 1–7
[4] Magnetic field dependence of the spin relaxation length in spin light-emitting diodes
H. Höpfner u. a.
Applied physics letters, Bd. 101, Nr. 11, S. 112402-1-112402–4, 2012
[5] Erratum:
H. Höpfner u. a.
Room temperature spin relaxation length in spin light-emitting diodes”: [Appl. Phys. Lett. 99, 051102 (2011)]“, Applied physics letters, Bd. 100, Nr. 26, S. 269902–1, 2012
[6] Temperature dependence of the spin relaxation length in spin quantum dot LEDs
C. Fritsche u. a.
Verhandlungen der Deutschen Physikalischen Gesellschaft, Bd. 6. Reihe, Bd 47, Nr. 4, 2012
[7] Spin relaxation dynamics in spin-LEDs
H. Höpfner u. a.
Verhandlungen der Deutschen Physikalischen Gesellschaft, Bd. 6. Reihe, Bd 47, Nr. 4, 2012
[8] Publisher’s note: Probing single-charge fluctuations at a GaAs/AlAs interface using laser spectroscopy on a nearby InGaAs quantum dot [Phys. Rev. Lett. 108, 107401 (2012)]
J. Houel u. a.
Physical review letters, Bd. 108, Nr. 11, S. 119902(E), 2012
[9] Capacitance-voltage spectroscopy of InAs quantum dots under external applied strain
S. Valentin, A. Ludwig, D. Reuter, und A. Wieck
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Regensburg, 2012, Bd. 6. Reihe, Bd 51, Nr. 3
2011
[1] Elektrische Spininjektion in InAs-Quantenpunkte
A. Ludwig und A. Wieck
Universitätsbibliothek, Ruhr-Universität Bochum, Bochum, 2011
[2] Optically detected nuclear magnetic resonance in n-GaAs using an on-chip microcoil
Y. S. Chen, J. Huang, D. Reuter, A. Ludwig, A. Wieck, und G. Bacher
Applied physics letters, Bd. 98, Nr. 8, S. 081911-1-081911–3, 2011
[3] (1 0 0) GaAs/AlxGa1−xAs heterostructures for Zeeman spin splitting studies of hole quantum wires
K. Trunov u. a.
Journal of crystal growth, Bd. 323, Nr. 1, S. 48–51, 2011
[4] Einfluss von höherer Gate-Spannung und Lichteinfluss auf die Ladespektren von InAs-Quantenpunkt-Proben mit ITO-Gates
P. A. Labud, A. Ludwig, D. Reuter, und A. Wieck
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Dresden, 2011, Bd. 6. Reihe, Bd 46, Nr. 1
[5] Dynamic nuclear polarization in n-GaAs-free versus localized electrons
J. Huang, Y. Chen, A. Ludwig, D. Reuter, A. Wieck, und G. Bacher
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Dresden, 2011, Bd. 6. Reihe, Bd 46, Nr. 1
[6] Manipulation of nuclear spin dynamics in n-GaAs using an on-chip microcoil
Y. S. Chen, J. Huang, A. Ludwig, D. Reuter, A. Wieck, und G. Bacher
Journal of applied physics, Bd. 109, Nr. 1, S. 016106-1-016106–3, 2011
[7] Growth of GaN based structures on focused ion beam patterned templates
Y. Cordier u. a.
Physica status solidi C, Bd. 8, Nr. 5, S. 1516–1519, 2011
[8] Room temperature spin relaxation length in spin light-emitting diodes
H. Höpfner u. a.
Applied physics letters, Bd. 99, Nr. 5, 2011
[9] Perpendicular spin injection and polarization features in InAs quantum dots
A. Ludwig u. a.
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Dresden, 2011, Bd. 6. Reihe, Bd 46, Nr. 1
[10] Electrical spin injection in InAs quantum dots at room temperature and adjustment of the emission wavelength for spintronic applications
A. Ludwig u. a.
Journal of crystal growth, Bd. 323, Nr. 1, S. 376–379, 2011
[11] Remanent spin injection and spin relaxation in quantum dot light emitting diodes
H. Höpfner u. a.
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Dresden, 2011, Bd. 6. Reihe, Bd 46, Nr. 1
[12] MOCVD of ZnO films from bis(ketoiminato)Zn(II) precursors: structure, morphology and optical properties
D. Bekermann u. a.
Chemical vapor deposition, Bd. 17, S. 155–161, 2011
[13] Transport properties of ferromagnet-semiconductor hybrid
L. Ravindran u. a.
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Dresden, 2011, Bd. 6. Reihe, Bd 46, Nr. 1
[14] Herstellung, Kontaktierung und Charakterisierung von GaAs Mikro-Photovoltaikzellen
M. Kwiatek, A. Ludwig, R. Schott, und A. Wieck
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Dresden, 2011, Bd. 6. Reihe, Bd 46, Nr. 1
[15] Carbon implantation in GaAs by focused ion beam and electrical activation by rapid thermal annealing
M. Greff, A. Ludwig, D. Reuter, und A. Wieck
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Dresden, 2011, Bd. 6. Reihe, Bd 46, Nr. 1
[16] Overview of RF high-permeability ferromagnetic thin films and its application to a new ferromagnetic/conductive multilayer to suppress skin effect in RF on-chip conductors
M. Yamaguchi, Y. Endo, N. Sato, und A. Ludwig
in 2011 6TH EUROPEAN MICROWAVE INTEGRATED CIRCUIT CONFERENCE, Jan. 2011, S. 7780.
2010
[1] Properties of spin.optoelectronic-devices
N. C. Gerhardt u. a.
5. Juli 2010.
[2] Ladungsträgerdichtesteuerung in einer invertierten GaAs/AlxGa1-xAs Heterostruktur mit eingebetteten InAs Quantenpunkten mittels Rückseitengate
S. Valentin, A. Ludwig, D. Reuter, und A. Wieck
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Regensburg, 2010, Bd. 6. Reihe, Bd 45, Nr. 3
[3] Ladespektroskopie unter optischer Anregung an InAs-Quantenpunkten
P. A. Labud, D. Reuter, A. Ludwig, A. K. Rai, und A. Wieck
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Regensburg, 2010, Bd. 6. Reihe, Bd 45, Nr. 3
[4] Epitaxial growth and interfacial magnetism of spin aligner for remanent spin injection: [Fe/Tb]n/Fe/MgO/GaAs-light emitting diode as a prototype system
E. U. Schuster u. a.
Journal of applied physics, Bd. 108, Nr. 6, S. 1–4, 2010
[5] Structural and magnetic investigations of Fe and Fe3Si as CEO-grown spin aligning layers on spin LEDs
S. Noor u. a.
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Regensburg, 2010, Bd. 6. Reihe, Bd 45, Nr. 3
2009
[1] Fabrication and analysis of Fe and Fe/MgO films on the GaAs(110) cleaved edge of an LED structure for spin injection
H. Harutyunyan u. a.
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Dresden, 2009, Bd. 6. Reihe, Bd 44, Nr. 5
2008
[1] Room temperature electrical spin injection in remanence
S. Hövel u. a.
Applied physics letters, Bd. 93, Nr. 2, S. 1–3, 2008
2007
[1] From a gate voltage scale to an energy scale in capacitance voltage spectroscopy of InAs quantum dots
A. Ludwig, D. Reuter, und A. Wieck
in Verhandlungen der Deutschen Physikalischen Gesellschaft, Regensburg, 2007, Bd. 6. Reihe, Bd 42, Nr. 4
2001
[1] A monolithiated and its related 1,3-dilithiated benzylsilane: syntheses and crystal structures
C. Strohmann, K. Lehmen, A. Ludwig, und D. Schildbach
Organometallics, Bd. 20, Nr. 20, S. 4138–4140, 2001
1998
[1] Warmhärte und Eigenspannungen nitrierter Stähle
H.-J. Spies, H. Berns, A. Ludwig, K. Bambauer, und U. Brusky
Härterei-technische Mitteilungen, Bd. 53, Nr. 6, S. 359–366, 1998.
Ohne Angabe
[1] Wafer, optical emission device, method of producing a wafer, and method of characterizing a system for producing a wafer
C. Dangel u. a.
17 /595,738