@article{58092,
  author       = {{Carr, Alex D.  and Ruppert, Claudia  and Samusev, Anton K.  and Magnabosco, Giulia  and Vogel, Nicolas  and Linnik, Tetiana L.  and Rushforth, Andrew W.  and Bayer, Manfred  and Scherbakov, Alexey V.  and Akimov, Andrey V. }},
  journal      = {{ACS Photonics}},
  number       = {{3}},
  title        = {{{Enhanced Photon–Phonon Interaction in WSe2 Acoustic Nanocavities}}},
  doi          = {{10.1021/acsphotonics.3c01601}},
  volume       = {{11}},
  year         = {{2024}},
}

@article{58091,
  author       = {{Li, Changxiu  and Scherbakov, Alexey V.  and Soubelet, Pedro  and Samusev, Anton K.  and Ruppert, Claudia  and Balakrishnan, Nilanthy  and Gusev, Vitalyi E.  and Stier, Andreas V.  and Finley, Jonathan J.  and Bayer, Manfred  and Akimov, Andrey V. }},
  journal      = {{Nano Letters}},
  number       = {{17}},
  title        = {{{Coherent Phonons in van der Waals MoSe2/WSe2 Heterobilayers}}},
  doi          = {{10.1021/acs.nanolett.3c02316}},
  volume       = {{23}},
  year         = {{2023}},
}

@article{58093,
  author       = {{Nitschke, Jonah Elias  and Esteras, Dorye L.  and Gutnikov, Michael  and Schiller, Karl  and Mañas-Valero, Samuel  and Coronado, Eugenio  and Stupar, Matija  and Zamborlini, Giovanni  and Ponzoni, Stefano  and Baldoví, José J.  and Cinchetti, Mirko }},
  journal      = {{Materials Today Electronics}},
  title        = {{{Valence band electronic structure of the van der Waals antiferromagnet FePS3}}},
  doi          = {{10.1016/j.mtelec.2023.100061}},
  volume       = {{6}},
  year         = {{2023}},
}

@article{36804,
  author       = {{Henksmeier, Tobias and Schulz, Johann Friedemann and Kluth, Elias and Feneberg, Martin and Goldhahn, Rüdiger and Sanchez, Ana M. and Voigt, Markus and Grundmeier, Guido and Reuter, Dirk}},
  journal      = {{Journal of Crystal Growth}},
  publisher    = {{Elsevier}},
  title        = {{{Remote epitaxy of In(x)Ga(1-x)As(001) on graphene covered GaAs(001) substrates}}},
  doi          = {{10.1016/j.jcrysgro.2022.126756}},
  volume       = {{593}},
  year         = {{2022}},
}

@article{58087,
  author       = {{Akimov, Andrey V.  and Barra-Burillo, María  and Bayer, Manfred  and Bradford, Jonathan  and Gusev, Vitalyi E.  and Hueso, Luis E.  and Kent, Anthony  and Kukhtaruk, Serhii  and Nadzeyka, Achim  and Patanè, Amalia  and Rushforth, Andrew W.  and Scherbakov, Alexey V.  and Yaremkevich, Dmytro D.  and Linnik, Tetiana L. }},
  journal      = {{Nano Letters}},
  number       = {{16}},
  title        = {{{Coherent Phononics of van der Waals Layers on Nanogratings}}},
  doi          = {{10.1021/acs.nanolett.2c01542}},
  volume       = {{22}},
  year         = {{2022}},
}

@article{58089,
  author       = {{Demenev, A.A.  and Yaremkevich, D.D.  and Scherbakov, A.V.  and Gavrilov, S.S.  and Yakovlev, D.R.  and Kulakovskii, V.D.  and Bayer, M. }},
  journal      = {{Physical Review Applied}},
  title        = {{{Ultrafast All-Optical Polarization Switch Controlled by Optically Excited Picosecond Acoustic Perturbation of Exciton Resonance in Planar Microcavities}}},
  doi          = {{10.1103/PhysRevApplied.18.044045}},
  volume       = {{18}},
  year         = {{2022}},
}

@article{20592,
  abstract     = {{GaAs-(111)-nanostructures exhibiting second harmonic generation are new building blocks in nonlinear optics. Such structures can be fabricated through epitaxial lift-off using selective etching of Al-containing layers and subsequent transfer to glass substrates. Herein, the selective etching of (111)B-oriented AlxGa1−xAs sacrificial layers (10–50 nm thick) with different aluminum concentrations (x = 0.5–1.0) in 10\% hydrofluoric acid is investigated and compared with standard (100)-oriented structures. The thinner the sacrificial layer and the lower the aluminum content, the lower the lateral etch rate. For both orientations, the lateral etch rates are in the same order of magnitude, but some quantitative differences exist. Furthermore, the epitaxial lift-off, the transfer, and the nanopatterning of thin (111)B-oriented GaAs membranes are demonstrated. Atomic force microscopy and high-resolution X-ray diffraction measurements reveal the high structural quality of the transferred GaAs-(111) films.}},
  author       = {{Henksmeier, Tobias and Eppinger, Martin and Reineke, Bernhard and Zentgraf, Thomas and Meier, Cedrik and Reuter, Dirk}},
  journal      = {{physica status solidi (a)}},
  keywords     = {{epitaxial lift-off, GaAs/AlxGa1−xAs heterostructures, selective etching}},
  number       = {{3}},
  pages        = {{2000408}},
  title        = {{{Selective Etching of (111)B-Oriented AlxGa1−xAs-Layers for Epitaxial Lift-Off}}},
  doi          = {{https://doi.org/10.1002/pssa.202000408}},
  volume       = {{218}},
  year         = {{2021}},
}

@article{25227,
  abstract     = {{<jats:title>Abstract</jats:title><jats:p>Quantum well (QW) heterostructures have been extensively used for the realization of a wide range of optical and electronic devices. Exploiting their potential for further improvement and development requires a fundamental understanding of their electronic structure. So far, the most commonly used experimental techniques for this purpose have been all-optical spectroscopy methods that, however, are generally averaging in momentum space. Additional information can be gained by angle-resolved photoelectron spectroscopy (ARPES), which measures the electronic structure with momentum resolution. Here we report on the use of extremely low-energy ARPES (photon energy ~ 7 eV) to increase depth sensitivity and access buried QW states, located at 3 nm and 6 nm below the surface of cubic-GaN/AlN and GaAs/AlGaAs heterostructures, respectively. We find that the QW states in cubic-GaN/AlN can indeed be observed, but not their energy dispersion, because of the high surface roughness. The GaAs/AlGaAs QW states, on the other hand, are buried too deep to be detected by extremely low-energy ARPES. Since the sample surface is much flatter, the ARPES spectra of the GaAs/AlGaAs show distinct features in momentum space, which can be reconducted to the band structure of the topmost surface layer of the QW structure. Our results provide important information about the samples’ properties required to perform extremely low-energy ARPES experiments on electronic states buried in semiconductor heterostructures.</jats:p>}},
  author       = {{Hajlaoui, Mahdi and Ponzoni, Stefano and Deppe, Michael and Henksmeier, Tobias and As, Donat Josef and Reuter, Dirk and Zentgraf, Thomas and Springholz, Gunther and Schneider, Claus Michael and Cramm, Stefan and Cinchetti, Mirko}},
  issn         = {{2045-2322}},
  journal      = {{Scientific Reports}},
  title        = {{{Extremely low-energy ARPES of quantum well states in cubic-GaN/AlN and GaAs/AlGaAs heterostructures}}},
  doi          = {{10.1038/s41598-021-98569-6}},
  volume       = {{11}},
  year         = {{2021}},
}

@article{58083,
  author       = {{Yaremkevich, Dmytro D.  and Scherbakov, Alexey V.  and Kukhtaruk, Serhii M.  and Linnik, Tetiana L.  and Khokhlov, Nikolay E.  and Godejohann, Felix  and Dyatlova, Olga A.  and Nadzeyka, Achim  and Pattnaik, Debi P.  and Wang, Mu  and Roy, Syamashree  and Campion, Richard P.  and Rushforth, Andrew W.  and Gusev, Vitalyi E.  and Akimov, Andrey V.  and Bayer, Manfred }},
  journal      = {{ACS Nano}},
  number       = {{3}},
  title        = {{{Protected Long-Distance Guiding of Hypersound Underneath a Nanocorrugated Surface}}},
  doi          = {{10.1021/acsnano.0c09475}},
  volume       = {{15}},
  year         = {{2021}},
}

@article{58084,
  author       = {{Rolle, Konrad  and Yaremkevich, Dmytro  and Scherbakov, Alexey V.  and Bayer, Manfred  and Fytas, George }},
  journal      = {{Nature Scientific Reports}},
  title        = {{{Lifting restrictions on coherence loss when characterizing non-transparent hypersonic phononic crystals}}},
  doi          = {{10.1038/s41598-021-96663-3}},
  volume       = {{11}},
  year         = {{2021}},
}

@article{58081,
  author       = {{Kobecki, Michal  and Tandoi, Giuseppe  and Di Gaetano, Eugenio  and Sorel, Marc  and Scherbakov, Alexey V.  and Czerniuk, Thomas  and Schneider, Christian  and Kamp, Martin  and Höfling, Sven  and Akimov, Andrey V.  and Bayer, Manfred }},
  journal      = {{Ultrasonics}},
  publisher    = {{Elsevier}},
  title        = {{{Picosecond ultrasonics with miniaturized semiconductor lasers}}},
  doi          = {{10.1016/j.ultras.2020.106150}},
  volume       = {{106}},
  year         = {{2020}},
}

@misc{58057,
  author       = {{Demenev, A.A. and Yaremkevich, D.D. and Scherbakov, A.V.  and Kukhtaruk, S.M. and Gavrilov, S.S. and Yakolev, D.R.  and Kulakovskii, V.D. and Bayer, M.}},
  booktitle    = {{Physical Review B}},
  title        = {{{Ultrafast strain-induced switching of a bistable cavity-polariton system}}},
  year         = {{2019}},
}

@article{20588,
  abstract     = {{We have investigated the stacking of self-assembled cubic GaN quantum dots (QDs) grown in Stranski–Krastanov (SK) growth mode. The number of stacked layers is varied to compare their optical properties. The growth is in situ controlled by reflection high energy electron diffraction to prove the SK QD growth. Atomic force and transmission electron microscopy show the existence of wetting layer and QDs with a diameter of about 10 nm and a height of about 2 nm. The QDs have a truncated pyramidal form and are vertically aligned in growth direction. Photoluminescence measurements show an increase of the intensity with increasing number of stacked QD layers. Furthermore, a systematic blue-shift of 120 meV is observed with increasing number of stacked QD layers. This blueshift derives from a decrease in the QD height, because the QD height has also been the main confining dimension in our QDs.}},
  author       = {{Blumenthal, Sarah and Rieger, Torsten and Meertens, Doris and Pawlis, Alexander and Reuter, Dirk and As, Donat Josef}},
  issn         = {{0370-1972}},
  journal      = {{physica status solidi (b)}},
  keywords     = {{cubic crystals, GaN, molecular beam epitaxy, quantum dots}},
  number       = {{3}},
  pages        = {{1600729}},
  title        = {{{Stacked Self-Assembled Cubic GaN Quantum Dots Grown by Molecular Beam Epitaxy}}},
  doi          = {{https://doi.org/10.1002/pssb.201600729}},
  volume       = {{255}},
  year         = {{2018}},
}

@article{6540,
  abstract     = {{Coherent phonons can greatly vary light–matter interaction in semiconductor nanostructures placed inside an optical resonator on a picosecond time scale. For an ensemble of quantum dots (QDs) as active laser medium, phonons are able to induce a large enhancement or attenuation of the emission intensity, as has been recently demonstrated. The physics of this coupled phonon–exciton–light system consists of various effects, which in the experiment typically cannot be clearly separated, in particular, due to the complicated sample structure a rather complex strain pulse impinges on the QD ensemble. Here we present a comprehensive theoretical study how the laser emission is affected by phonon pulses of various shapes as well as by ensembles with different spectral distributions of the QDs. This gives insight into the fundamental interaction dynamics of the coupled phonon–exciton–light system, while it allows us to clearly discriminate between two prominent effects: the adiabatic shifting of the ensemble and the shaking effect. This paves the way to a tailored laser emission controlled by phonons.}},
  author       = {{Wigger, Daniel and Czerniuk, Thomas and Reiter, Doris E and Bayer, Manfred and Kuhn, Tilmann}},
  issn         = {{1367-2630}},
  journal      = {{New Journal of Physics}},
  number       = {{7}},
  publisher    = {{IOP Publishing}},
  title        = {{{Systematic study of the influence of coherent phonon wave packets on the lasing properties of a quantum dot ensemble}}},
  doi          = {{10.1088/1367-2630/aa78bf}},
  volume       = {{19}},
  year         = {{2017}},
}

@article{6544,
  abstract     = {{A picosecond acoustic pulse can be used to control the lasing emission from semiconductor nanostructures by shifting their electronic transitions. When the active medium, here an ensemble of (In,Ga)As quantum dots, is shifted into or out of resonance with the cavity mode, a large enhancement or suppression of the lasing emission can dynamically be achieved. Most interesting, even in the case when gain medium and cavity mode are in resonance, we observe an enhancement of the lasing due to shaking by coherent phonons. In order to understand the interactions of the nonlinearly coupled photon-exciton-phonon subsystems, we develop a semiclassical model and find an excellent agreement between theory and experiment.}},
  author       = {{Czerniuk, T. and Wigger, D. and Akimov, A. V. and Schneider, C. and Kamp, M. and Höfling, S. and Yakovlev, D. R. and Kuhn, T. and Reiter, D. E. and Bayer, M.}},
  issn         = {{0031-9007}},
  journal      = {{Physical Review Letters}},
  number       = {{13}},
  publisher    = {{American Physical Society (APS)}},
  title        = {{{Picosecond Control of Quantum Dot Laser Emission by Coherent Phonons}}},
  doi          = {{10.1103/physrevlett.118.133901}},
  volume       = {{118}},
  year         = {{2017}},
}

@article{6545,
  abstract     = {{We develop a nanoscopy method with in-depth resolution for layered photonic devices. Photonics often requires tailored light field distributions for the optical modes used, and an exact knowledge of the geometry of a device is crucial to assess its performance. The presented acousto-optical nanoscopy method is based on the uniqueness of the light field distributions in photonic devices: for a given wavelength, we record the reflectivity modulation during the transit of a picosecond acoustic pulse. The temporal profile obtained can be linked to the internal light field distribution. From this information, a reverse-engineering procedure allows us to reconstruct the light field and the underlying photonic structure very precisely. We apply this method to the slow light mode of an AlAs/GaAs micropillar resonator and show its validity for the tailored experimental conditions.}},
  author       = {{Czerniuk, T. and Schneider, C. and Kamp, M. and Höfling, S. and Glavin, B. A. and Yakovlev, D. R. and Akimov, A. V. and Bayer, M.}},
  issn         = {{2334-2536}},
  journal      = {{Optica}},
  number       = {{6}},
  publisher    = {{The Optical Society}},
  title        = {{{Acousto-optical nanoscopy of buried photonic nanostructures}}},
  doi          = {{10.1364/optica.4.000588}},
  volume       = {{4}},
  year         = {{2017}},
}

@article{6524,
  abstract     = {{We use a picosecond acoustics technique to modulate the laser output of electrically pumped GaAs/AlAs micropillar lasers with InGaAs quantum dots. The modulation of the emission wavelength takes place on the frequencies of the nanomechanical extensional and breathing (radial) modes of the micropillars. The amplitude of the modulation for various nanomechanical modes is different for every micropillar which is explained by a various elastic contact between the micropillar walls and polymer environment.}},
  author       = {{Czerniuk, T. and Tepper, J. and Akimov, A. V. and Unsleber, S. and Schneider, C. and Kamp, M. and Höfling, S. and Yakovlev, D. R. and Bayer, M.}},
  issn         = {{0003-6951}},
  journal      = {{Applied Physics Letters}},
  number       = {{4}},
  publisher    = {{AIP Publishing}},
  title        = {{{Impact of nanomechanical resonances on lasing from electrically pumped quantum dot micropillars}}},
  doi          = {{10.1063/1.4906611}},
  volume       = {{106}},
  year         = {{2015}},
}

