@article{63160,
author = {{Rose, Hendrik and Schumacher, Stefan and Meier, Torsten}},
issn = {{2469-9950}},
journal = {{Physical Review B}},
number = {{24}},
publisher = {{American Physical Society (APS)}},
title = {{{Microscopic approach to the quantized light-matter interaction in semiconductor nanostructures: Complex coupled dynamics of excitons, biexcitons, and photons}}},
doi = {{10.1103/528f-7smh}},
volume = {{112}},
year = {{2025}},
}
@inproceedings{55268,
author = {{Rose, Hendrik and Sharapova, Polina R. and Meier, Torsten}},
booktitle = {{Ultrafast Phenomena and Nanophotonics XXVIII}},
editor = {{Betz, Markus and Elezzabi, Abdulhakem Y.}},
publisher = {{SPIE}},
title = {{{Microscopic simulations of the dynamics of excitonic many-body correlations coupled to quantum light}}},
doi = {{10.1117/12.2690245}},
year = {{2024}},
}
@article{58218,
author = {{Grisard, Stefan and Trifonov, Artur V. and Hahn, Thilo and Kuhn, Tilmann and Hordiichuk, Oleh and Kovalenko, Maksym V. and Yakovlev, Dmitri R. and Bayer, Manfred and Akimov, Ilya A. }},
journal = {{ACS Photonics}},
number = {{8}},
title = {{{Spin-Dependent Exciton–Exciton Interactions in a Mixed Lead Halide Perovskite Crystal}}},
doi = {{https://doi.org/10.1021/acsphotonics.4c00499}},
volume = {{11}},
year = {{2024}},
}
@misc{53298,
abstract = {{Dataset of the publication "Theoretical analysis of four-wave mixing on semiconductor quantum dot ensembles with quantum light" H. Rose, S. Grisard, A. V. Trifonov, R. Reichhardt, M. Reichelt, M. Bayer, I. A. Akimov, and T. Meier, Proc. SPIE 12419, Ultrafast Phenomena and Nanophotonics XXVII, 124190H (2023). ( https://doi.org/10.1117/12.2647700 ). The zip file includes the data on which the plots shown in figures 1 and 2 are based.}},
author = {{Rose, Hendrik and Grisard, Stefan and Trifonov, Artur V. and Reichhardt, Rilana and Reichelt, Matthias and Bayer, Manfred and Akimov, Ilya A. and Meier, Torsten}},
publisher = {{LibreCat University}},
title = {{{Theoretical analysis of four-wave mixing on semiconductor quantum dot ensembles with quantum light}}},
doi = {{10.5281/ZENODO.7755761}},
year = {{2023}},
}
@article{55901,
author = {{Grisard, Stefan and Trifonov, Artur V. and Rose, Hendrik and Reichhardt, Rilana and Reichelt, Matthias and Schneider, Christian and Kamp, Martin and Höfling, Sven and Bayer, Manfred and Meier, Torsten and Akimov, Ilya A.}},
issn = {{2330-4022}},
journal = {{ACS Photonics}},
number = {{9}},
pages = {{3161--3170}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Temporal Sorting of Optical Multiwave-Mixing Processes in Semiconductor Quantum Dots}}},
doi = {{10.1021/acsphotonics.3c00530}},
volume = {{10}},
year = {{2023}},
}
@article{37280,
author = {{Rose, Hendrik and Vasil'ev, A. N. and Tikhonova, O. V. and Meier, Torsten and Sharapova, Polina}},
issn = {{2469-9926}},
journal = {{Physical Review A}},
number = {{1}},
publisher = {{American Physical Society (APS)}},
title = {{{Quantum-optical excitations of semiconductor nanostructures in a microcavity using a two-band model and a single-mode quantum field}}},
doi = {{10.1103/physreva.107.013703}},
volume = {{107}},
year = {{2023}},
}
@unpublished{43132,
author = {{Meier, Torsten and Grisard, S. and Trifonov, A.V. and Rose, Hendrik and Reichhardt, R. and Reichelt, Matthias and Schneider, C. and Kamp, M. and Höfling, S. and Bayer, M. and Akimov, I.A}},
booktitle = {{arxiv:2302.02480}},
title = {{{Temporal sorting of optical multi-wave-mixing processes in semiconductor quantum dots}}},
year = {{2023}},
}
@inproceedings{43192,
abstract = {{The nonlinear optical response of an ensemble of semiconductor quantum dots is analyzed by wave-mixing processes, where we focus on four-wave mixing with two incident pulses. Wave-mixing experiments are often described with semiclassical models, where the light is modeled classically and the material quantum mechanically. Here, however, we use a fully quantized model, where the light is given by a quantum state of light. Quantum light involves more degrees of freedom than classical light as e.g., its photon statistics and quantum correlations, which is a promising resource for quantum devices, such as quantum memories. The light-matter interaction is treated with a Jaynes-Cummings type model and the quantum field is given by a single mode since the quantum dots are embedded in a microcavity. We present numerical simulations of the four-wave-mixing response of a homogeneous system for pulse sequences and find a significant dependence of the result on the photon statistics of the incident pulses. The model constitutes a problem with a large state space which arises from the frequency distribution of the transition energies of the inhomogeneously broadened quantum dot ensemble that is coupled with a quantum light mode. Here we approximate the dynamics by summing over individual quantum dot-microcavity systems. Photon echoes arising from the excitation with different quantum states of light are simulated and compared.}},
author = {{Rose, Hendrik and Grisard, S. and Trifonov, A. V. and Reichhardt, R. and Reichelt, Matthias and Bayer, M. and Akimov, I. A. and Meier, Torsten}},
booktitle = {{Ultrafast Phenomena and Nanophotonics XXVII}},
publisher = {{SPIE}},
title = {{{Theoretical analysis of four-wave mixing on semiconductor quantum dot ensembles with quantum light}}},
doi = {{10.1117/12.2647700}},
volume = {{12419}},
year = {{2023}},
}
@article{58222,
author = {{Grisard, Stefan and Trifonov, Artur V. and Solovev, Ivan A. and Yakovlev, Dmitri R. and Hordiichuk, Oleh and Kovalenko, Maksym V. and Bayer, Manfred and Akimov, Ilya A. }},
journal = {{Nano Letters}},
number = {{16}},
title = {{{Long-Lived Exciton Coherence in Mixed-Halide Perovskite Crystals}}},
doi = {{https://doi.org/10.1021/acs.nanolett.3c01817}},
volume = {{23}},
year = {{2023}},
}
@article{31828,
author = {{Kupfer, Robert and Köhler, Daniel and Römisch, David and Wituschek, Simon and Ewenz, Lars and Kalich, Jan and Weiß, Deborah and Sadeghian, Behdad and Busch, Matthias and Krüger, Jan and Neuser, Moritz and Grydin, Olexandr and Böhnke, Max and Bielak, Christian Roman and Troschitz, Juliane}},
issn = {{2666-3309}},
journal = {{Journal of Advanced Joining Processes}},
keywords = {{Mechanical Engineering, Mechanics of Materials, Engineering (miscellaneous), Chemical Engineering (miscellaneous)}},
publisher = {{Elsevier BV}},
title = {{{Clinching of Aluminum Materials – Methods for the Continuous Characterization of Process, Microstructure and Properties}}},
doi = {{10.1016/j.jajp.2022.100108}},
volume = {{5}},
year = {{2022}},
}
@article{37323,
author = {{Paul, J. and Rose, Hendrik and Swagel, E. and Meier, Torsten and Wahlstrand, J. K. and Bristow, A. D.}},
issn = {{2469-9950}},
journal = {{Physical Review B}},
number = {{11}},
publisher = {{American Physical Society (APS)}},
title = {{{Coherent contributions to population dynamics in a semiconductor microcavity}}},
doi = {{10.1103/physrevb.105.115307}},
volume = {{105}},
year = {{2022}},
}
@article{37338,
abstract = {{AbstractMethylammonium lead iodide perovskite (MAPbI3) is renowned for an impressive power conversion efficiency rise and cost-effective fabrication for photovoltaics. In this work, we demonstrate that polycrystalline MAPbI3s undergo drastic changes in optical properties at moderate field strengths with an ultrafast response time, via transient Wannier Stark localization. The distinct band structure of this material - the large lattice periodicity, the narrow electronic energy bandwidths, and the coincidence of these two along the same high-symmetry direction – enables relatively weak fields to bring this material into the Wannier Stark regime. Its polycrystalline nature is not detrimental to the optical switching performance of the material, since the least dispersive direction of the band structure dominates the contribution to the optical response, which favors low-cost fabrication. Together with the outstanding photophysical properties of MAPbI3, this finding highlights the great potential of this material in ultrafast light modulation and novel photonic applications.}},
author = {{Berghoff, Daniel and Bühler, Johannes and Bonn, Mischa and Leitenstorfer, Alfred and Meier, Torsten and Kim, Heejae}},
issn = {{2041-1723}},
journal = {{Nature Communications}},
keywords = {{General Physics and Astronomy, General Biochemistry, Genetics and Molecular Biology, General Chemistry, Multidisciplinary}},
number = {{1}},
publisher = {{Springer Science and Business Media LLC}},
title = {{{Low-field onset of Wannier-Stark localization in a polycrystalline hybrid organic inorganic perovskite}}},
doi = {{10.1038/s41467-021-26021-4}},
volume = {{12}},
year = {{2021}},
}
@inproceedings{23474,
author = {{Reichelt, Matthias and Rose, Hendrik and Kosarev, Alexander N. and Poltavtsev, Sergey V. and Bayer, Manfred and Akimov, Ilya A. and Schneider, Christian and Kamp, Martin and Höfling, Sven and Meier, Torsten}},
booktitle = {{Ultrafast Phenomena and Nanophotonics XXV}},
editor = {{Betz, Markus and Elezzabi, Abdulhakem Y.}},
title = {{{Controlling the emission time of photon echoes by optical freezing of exciton dephasing and rephasing in quantum-dot ensembles}}},
doi = {{10.1117/12.2576887}},
volume = {{11684}},
year = {{2021}},
}
@article{20773,
abstract = {{AbstractSemiconductor quantum dots are excellent candidates for ultrafast coherent manipulation of qubits by laser pulses on picosecond timescales or even faster. In inhomogeneous ensembles a macroscopic optical polarization decays rapidly due to dephasing, which, however, is reversible in photon echoes carrying complete information about the coherent ensemble dynamics. Control of the echo emission time is mandatory for applications. Here, we propose a concept to reach this goal. In a two-pulse photon echo sequence, we apply an additional resonant control pulse with multiple of 2π area. Depending on its arrival time, the control slows down dephasing or rephasing of the exciton ensemble during its action. We demonstrate for self-assembled (In,Ga)As quantum dots that the photon echo emission time can be retarded or advanced by up to 5 ps relative to its nominal appearance time without control. This versatile protocol may be used to obtain significantly longer temporal shifts for suitably tailored control pulses.}},
author = {{Kosarev, Alexander N. and Rose, Hendrik and Poltavtsev, Sergey V. and Reichelt, Matthias and Schneider, Christian and Kamp, Martin and Höfling, Sven and Bayer, Manfred and Meier, Torsten and Akimov, Ilya A.}},
issn = {{2399-3650}},
journal = {{Communications Physics}},
number = {{1}},
title = {{{Accurate photon echo timing by optical freezing of exciton dephasing and rephasing in quantum dots}}},
doi = {{10.1038/s42005-020-00491-2}},
volume = {{3}},
year = {{2020}},
}
@article{20563,
author = {{Hannes, W.-R. and Trautmann, Alexander and Stein, M. and Schäfer, F. and Koch, M. and Meier, Torsten}},
journal = {{Physical Review B}},
number = {{7}},
pages = {{075203}},
publisher = {{American Physical Society}},
title = {{{Strongly nonresonant four-wave mixing in semiconductors}}},
doi = {{10.1103/PhysRevB.101.075203}},
volume = {{101}},
year = {{2020}},
}
@article{14544,
author = {{Vondran, J. and Spitzer, F. and Bayer, M. and Akimov, I. A. and Trautmann, Alexander and Reichelt, Matthias and Meier, Cedrik and Weber, N. and Meier, Torsten and André, R. and Mariette, H.}},
issn = {{2469-9950}},
journal = {{Physical Review B}},
number = {{15}},
pages = {{155308}},
title = {{{Spatially asymmetric transients of propagating exciton-polariton modes in a planar CdZnTe/CdMgTe guiding structure}}},
doi = {{10.1103/physrevb.100.155308}},
volume = {{100}},
year = {{2019}},
}
@article{22887,
author = {{Vondran, J. and Spitzer, F. and Bayer, M. and Akimov, I. A. and Trautmann, Alexander and Reichelt, Matthias and Meier, Cedrik and Weber, N. and Meier, Torsten and André, R. and Mariette, H.}},
issn = {{2469-9950}},
journal = {{Physical Review B}},
number = {{15}},
pages = {{155308}},
title = {{{Spatially asymmetric transients of propagating exciton-polariton modes in a planar CdZnTe/CdMgTe guiding structure}}},
doi = {{10.1103/physrevb.100.155308}},
volume = {{100}},
year = {{2019}},
}
@article{4370,
author = {{Schmidt, C. and Bühler, J. and Heinrich, A.-C. and Allerbeck, J. and Podzimski, R. and Berghoff, D. and Meier, Torsten and Schmidt, Wolf Gero and Reichl, C. and Wegscheider, W. and Brida, D. and Leitenstorfer, A.}},
issn = {{2041-1723}},
journal = {{Nature Communications}},
number = {{1}},
publisher = {{Springer Nature}},
title = {{{Signatures of transient Wannier-Stark localization in bulk gallium arsenide}}},
doi = {{10.1038/s41467-018-05229-x}},
volume = {{9}},
year = {{2018}},
}
@article{10018,
author = {{Schmidt, Claudia and Bühler, J. and Heinrich, A.-C. and Allerbeck, J. and Podzimski, R. and Berghoff, Daniel and Meier, Torsten and Schmidt, Wolf Gero and Reichl, C. and Wegscheider, W. and Brida, D. and Leitenstorfer, A.}},
issn = {{2041-1723}},
journal = {{Nature Communications}},
title = {{{Signatures of transient Wannier-Stark localization in bulk gallium arsenide}}},
doi = {{10.1038/s41467-018-05229-x}},
volume = {{9}},
year = {{2018}},
}
@inproceedings{13901,
author = {{Akimov, Ilya and Poltavtsev, Sergey V. and Salewski, Matthias and Yugova, Irina A. and Karczewski, Grzegorz and Wojtowicz, Tomasz and Maciej, Wiater and Reichelt, Matthias and Meier, Torsten and Yakovlev, Dmitri and Bayer, Manfred}},
booktitle = {{Ultrafast Phenomena and Nanophotonics XXII}},
editor = {{Betz, Markus and Elezzabi, Abdulhakem Y.}},
isbn = {{9781510615458}},
publisher = {{SPIE}},
title = {{{Coherent optical spectroscopy of charged exciton complexes in semiconductor nanostructures}}},
doi = {{10.1117/12.2288788}},
volume = {{10530}},
year = {{2018}},
}