@article{50829,
author = {{Heinisch, Nils and Köcher, Nikolas and Bauch, David and Schumacher, Stefan}},
issn = {{2643-1564}},
journal = {{Physical Review Research}},
number = {{1}},
publisher = {{American Physical Society (APS)}},
title = {{{Swing-up dynamics in quantum emitter cavity systems: Near ideal single photons and entangled photon pairs}}},
doi = {{10.1103/PhysRevResearch.6.L012017}},
volume = {{6}},
year = {{2024}},
}
@article{51156,
abstract = {{Ferroelectric domain wall (DW) conductivity (DWC) can be attributed to two separate mechanisms: (a) the injection/ejection of charge carriers across the Schottky barrier formed at the (metal-)electrode-DW junction and (b) the transport of those charge carriers along the DW. Current-voltage (I-U) characteristics, recorded at variable temperatures from LiNbO3 (LNO) DWs, are clearly able to differentiate between these two contributions. Practically, they allow us to directly quantify the physical parameters relevant to the two mechanisms (a) and (b) mentioned above. These are, for example, the resistance of the DW, the saturation current, the ideality factor, and the Schottky barrier height of the electrode-DW junction. Furthermore, the activation energies needed to initiate the thermally activated electronic transport along the DWs can be extracted. In addition, we show that electronic transport along LNO DWs can be elegantly viewed and interpreted in an adapted semiconductor picture based on a double-diode, double-resistor equivalent-circuit model, the R2D2 model. Finally, our R2D2 model was checked for its universality by successfully fitting the I-U curves of not only z-cut LNO bulk DWs, but equally of z-cut thin-film LNO DWs, and of x-cut thin-film DWs as reported in literature.}},
author = {{Zahn, Manuel and Beyreuther, Elke and Kiseleva, Iuliia and Lotfy, Ahmed Samir and McCluskey, Conor J. and Maguire, Jesi R. and Suna, Ahmet and Rüsing, Michael and Gregg, J. Marty and Eng, Lukas M.}},
issn = {{2331-7019}},
journal = {{Physical Review Applied}},
keywords = {{General Physics and Astronomy}},
number = {{2}},
publisher = {{American Physical Society (APS)}},
title = {{{Equivalent-circuit model that quantitatively describes domain-wall conductivity in ferroelectric lithium }}},
doi = {{10.1103/physrevapplied.21.024007}},
volume = {{21}},
year = {{2024}},
}
@article{51339,
author = {{Babai-Hemati, Jonas and vom Bruch, Felix and Herrmann, Harald and Silberhorn, Christine}},
issn = {{1094-4087}},
journal = {{Optics Express}},
keywords = {{Atomic and Molecular Physics, and Optics}},
publisher = {{Optica Publishing Group}},
title = {{{Tailored second harmonic generation inTi-diffused PPLN waveguides usingmicro-heaters}}},
doi = {{10.1364/oe.510319}},
year = {{2024}},
}
@article{51519,
author = {{Cui, Tie Jun and Zhang, Shuang and Alu, Andrea and Wegener, Martin and Pendry, John and Luo, Jie and Lai, Yun and Wang, Zuojia and Lin, Xiao and Chen, Hongsheng and Chen, Ping and Wu, Rui-Xin and Yin, Yuhang and Zhao, Pengfei and Chen, Huanyang and Li, Yue and Zhou, Ziheng and Engheta, Nader and Asadchy, V. S. and Simovski, Constantin and Tretyakov, Sergei A and Yang, Biao and Campbell, Sawyer D. and Hao, Yang and Werner, Douglas H and Sun, Shulin and Zhou, Lei and Xu, Su and Sun, Hong-Bo and Zhou, Zhou and Li, Zile and Zheng, Guoxing and Chen, Xianzhong and Li, Tao and Zhu, Shi-Ning and Zhou, Junxiao and Zhao, Junxiang and Liu, Zhaowei and Zhang, Yuchao and Zhang, Qiming and Gu, Min and Xiao, Shumin and Liu, Yongmin and Zhang, Xiaoyu and Tang, Yutao and Li, Guixin and Zentgraf, Thomas and Koshelev, Kirill and Kivshar, Yuri S. and Li, Xin and Badloe, Trevon and Huang, Lingling and Rho, Junsuk and Wang, Shuming and Tsai, Din Ping and Bykov, A. Yu. and Krasavin, Alexey V and Zayats, Anatoly V and McDonnell, Cormac and Ellenbogen, Tal and Luo, Xiangang and Pu, Mingbo and Garcia-Vidal, Francisco J and Liu, Liangliang and Li, Zhuo and Tang, Wenxuan and Ma, Hui Feng and Zhang, Jingjing and Luo, Yu and Zhang, Xuanru and Zhang, Hao Chi and He, Pei Hang and Zhang, Le Peng and Wan, Xiang and Wu, Haotian and Liu, Shuo and Jiang, Wei Xiang and Zhang, Xin Ge and Qiu, Chengwei and Ma, Qian and Liu, Che and Li, Long and Han, Jiaqi and Li, Lianlin and Cotrufo, Michele and Caloz, Christophe and Deck-Léger, Z.-L. and Bahrami, A. and Céspedes, O. and Galiffi, Emanuele and Huidobro, P. A. and Cheng, Qiang and Dai, Jun Yan and Ke, Jun Cheng and Zhang, Lei and Galdi, Vincenzo and Di Renzo, Marco}},
issn = {{2515-7647}},
journal = {{Journal of Physics: Photonics}},
keywords = {{Electrical and Electronic Engineering, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials}},
publisher = {{IOP Publishing}},
title = {{{Roadmap on electromagnetic metamaterials and metasurfaces}}},
doi = {{10.1088/2515-7647/ad1a3b}},
year = {{2024}},
}
@article{51207,
abstract = {{Let $X=X_1\times X_2$ be a product of two rank one symmetric spaces of
non-compact type and $\Gamma$ a torsion-free discrete subgroup in $G_1\times
G_2$. We show that the spectrum of $\Gamma \backslash X$ is related to the
asymptotic growth of $\Gamma$ in the two direction defined by the two factors.
We obtain that $L^2(\Gamma \backslash G)$ is tempered for large class of
$\Gamma$.}},
author = {{Weich, Tobias and Wolf, Lasse Lennart}},
journal = {{Geom Dedicata}},
title = {{{Temperedness of locally symmetric spaces: The product case}}},
doi = {{https://doi.org/10.1007/s10711-024-00904-4}},
volume = {{218}},
year = {{2024}},
}
@article{54093,
author = {{Pinske, Julien and Sperling, Jan}},
issn = {{2469-9926}},
journal = {{Physical Review A}},
number = {{5}},
publisher = {{American Physical Society (APS)}},
title = {{{Unbreakable and breakable quantum censorship}}},
doi = {{10.1103/physreva.109.052408}},
volume = {{109}},
year = {{2024}},
}
@article{54017,
author = {{Kress, Christian and Schwabe, Tobias and Rhee, Hanjo and Scheytt, J. Christoph}},
issn = {{2169-3536}},
journal = {{IEEE Access}},
pages = {{1--1}},
publisher = {{Institute of Electrical and Electronics Engineers (IEEE)}},
title = {{{Compact, High-Speed Mach-Zehnder Modulator with On-Chip Linear Drivers in Photonic BiCMOS Technology}}},
doi = {{10.1109/access.2024.3396877}},
year = {{2024}},
}
@article{54544,
abstract = {{The biphoton correlation time, a measure for the conditional uncertainty in the temporal arrival of two photons from a photon pair source, is a key performance identifier for many quantum spectroscopy applications, with shorter correlation times typically yielding better performance. Furthermore, it provides fundamental insight into the effects of dispersion on the biphoton state. Here, we show that a characteristic dependence of the width of the temporal interferogram can be exploited to obtain insights into the amount of second-order dispersion inside the interferometer and to retrieve actual and Fourier-limited ultrashort biphoton correlation times of around 100 fs. In the presented scheme, we simultaneously measure spectral and temporal interferograms at the output of an SU(1,1) interferometer based on an integrated broadband parametric down conversion source in a Ti:LiNbO3 waveguide.}},
author = {{Roeder, Franz and Pollmann, René and Stefszky, Michael and Santandrea, Matteo and Luo, Kai Hong and Quiring, V. and Ricken, Raimund and Eigner, Christof and Brecht, Benjamin and Silberhorn, Christine}},
issn = {{2691-3399}},
journal = {{PRX Quantum}},
number = {{2}},
publisher = {{American Physical Society (APS)}},
title = {{{Measurement of Ultrashort Biphoton Correlation Times with an Integrated Two-Color Broadband SU(1,1)-Interferometer}}},
doi = {{10.1103/prxquantum.5.020350}},
volume = {{5}},
year = {{2024}},
}
@article{54812,
author = {{Weinbrenner, Lisa T. and Prasannan, Nidhin and Hansenne, Kiara and Denker, Sophia and Sperling, Jan and Brecht, Benjamin and Silberhorn, Christine and Gühne, Otfried}},
issn = {{0031-9007}},
journal = {{Physical Review Letters}},
number = {{24}},
publisher = {{American Physical Society (APS)}},
title = {{{Certifying the Topology of Quantum Networks: Theory and Experiment}}},
doi = {{10.1103/physrevlett.132.240802}},
volume = {{132}},
year = {{2024}},
}
@article{55085,
abstract = {{The lithium niobate–lithium tantalate solid solution’s phase diagram was investigated using experimental data from differential thermal analysis (DTA) and crystal growth. We used XRF analysis to determine the elemental composition of the crystals. The Neumann–Kopp rule provided essential data for the end members lithium niobate (LN) and lithium tantalate (LT). The heats of fusion of the end members, given by DTA measurements, are 103 kJ/mol at 1531 K for LN and 289 kJ/mol at 1913 K for LT. These values were used as input parameters to generate the data. This data served as the basis for calculating a phase diagram for LN-LT solid solutions. Finally, based on the experimental data and a thermodynamic solution model, the Calphad Factsage module optimized the phase diagram. We also generated thermodynamic parameters for Gibbs’ excess energy of the solid solution. A plot of the segregation coefficient as a function of Ta concentration was derived from the phase diagram.}},
author = {{Bashir, Umar and Klimm, Detlef and Rüsing, Michael and Bickermann, Matthias and Ganschow, Steffen}},
issn = {{0022-2461}},
journal = {{Journal of Materials Science}},
publisher = {{Springer Science and Business Media LLC}},
title = {{{Evaluation and thermodynamic optimization of phase diagram of lithium niobate tantalate solid solutions}}},
doi = {{10.1007/s10853-024-09932-7}},
year = {{2024}},
}
@article{55140,
author = {{Yasmin, Farha and Sperling, Jan}},
issn = {{2469-9926}},
journal = {{Physical Review A}},
number = {{1}},
publisher = {{American Physical Society (APS)}},
title = {{{Entanglement-assisted quantum speedup: Beating local quantum speed limits}}},
doi = {{10.1103/physreva.110.012424}},
volume = {{110}},
year = {{2024}},
}
@article{55173,
author = {{Di Fidio, Christian and Ares, Laura and Sperling, Jan}},
issn = {{2469-9926}},
journal = {{Physical Review A}},
number = {{1}},
publisher = {{American Physical Society (APS)}},
title = {{{Quantum walks and entanglement in cavity networks}}},
doi = {{10.1103/physreva.110.013705}},
volume = {{110}},
year = {{2024}},
}
@article{55174,
abstract = {{We apply principal component analysis (PCA) to a set of electrical output signals from a commercially available superconducting nanowire single-photon detector (SNSPD) to investigate their photon-number-resolving capability. We find that the rising edge as well as the amplitude of the electrical signal have the most dependence on photon number. Accurately measuring the rising edge while simultaneously measuring the voltage of the pulse amplitude maximizes the photon-number resolution of SNSPDs. Using an optimal basis of principal components, we show unambiguous discrimination between one- and two-photon events, as well as partial resolution up to five photons. This expands the use case of SNSPDs to photon-counting experiments, without the need of detector multiplexing architectures.
Published by the American Physical Society
2024
}},
author = {{Schapeler, Timon and Lamberty, Niklas and Hummel, Thomas and Schlue, Fabian and Stefszky, Michael and Brecht, Benjamin and Silberhorn, Christine and Bartley, Tim}},
issn = {{2331-7019}},
journal = {{Physical Review Applied}},
number = {{1}},
publisher = {{American Physical Society (APS)}},
title = {{{Electrical trace analysis of superconducting nanowire photon-number-resolving detectors}}},
doi = {{10.1103/physrevapplied.22.014024}},
volume = {{22}},
year = {{2024}},
}
@article{54668,
abstract = {{Samples of dielectric optical waveguides of rib or strip type in thin-film lithium niobate (TFLN) technology are characterized with respect to their optical loss using the Fabry-Pérot method. Attributing the losses mainly to sidewall roughness, we employ a simple perturbational procedure, based on rigorously computed mode profiles of idealized channels, to estimate the attenuation for waveguides with different cross sections. A single fit parameter suffices for an adequate modelling of the effect of the waveguide geometry on the loss levels.}},
author = {{Hammer, Manfred and Babel, Silia and Farheen, Henna and Padberg, Laura and Scheytt, J. Christoph and Silberhorn, Christine and Förstner, Jens}},
issn = {{1094-4087}},
journal = {{Optics Express}},
keywords = {{tet_topic_waveguide}},
number = {{13}},
pages = {{22878}},
publisher = {{Optica Publishing Group}},
title = {{{Estimation of losses caused by sidewall roughness in thin-film lithium niobate rib and strip waveguides}}},
doi = {{10.1364/oe.521766}},
volume = {{32}},
year = {{2024}},
}
@article{55737,
abstract = {{We report on a photonic simulator of the critical state forming at the quantum phase transition between topologically distinct Anderson insulator phases. We observe a time-staggered profile in the circular photon polarization, which originates from the interplay of a chiral and sublattice symmetry, and has recently been suggested as a signature for topological Anderson criticality within the setup. We discuss the role of statistical detuning from criticality and show that the controlled breaking of phase coherence removes the signal, revealing its origin in quantum coherence.
Published by the American Physical Society
2024
}},
author = {{Barkhofen, Sonja and De, Syamsundar and Sperling, Jan and Silberhorn, Christine and Altland, Alexander and Bagrets, Dmitry and Kim, Kun Woo and Micklitz, Tobias}},
issn = {{2643-1564}},
journal = {{Physical Review Research}},
number = {{3}},
publisher = {{American Physical Society (APS)}},
title = {{{Experimental observation of topological quantum criticality}}},
doi = {{10.1103/physrevresearch.6.033194}},
volume = {{6}},
year = {{2024}},
}
@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{49652,
abstract = {{Broadband coherent anti-Stokes Raman scattering (BCARS) is a powerful spectroscopy method combining high signal intensity with spectral sensitivity, enabling rapid imaging of heterogeneous samples in biomedical research and, more recently, in crystalline materials. However, BCARS encounters spectral distortion due to a setup-dependent non-resonant background (NRB). This study assesses BCARS reproducibility through a round robin experiment using two distinct BCARS setups and crystalline materials with varying structural complexity, including diamond, 6H-SiC, KDP, and KTP. The analysis compares setup-specific NRB correction procedures, detected and NRB-removed spectra, and mode assignment. We determine the influence of BCARS setup parameters like pump wavelength, pulse width, and detection geometry and provide a practical guide for optimizing BCARS setups for solid-state applications.}},
author = {{Hempel, Franz and Vernuccio, Federico and König, Lukas and Buschbeck, Robin and Rüsing, Michael and Cerullo, Giulio and Polli, Dario and Eng, Lukas M.}},
issn = {{1559-128X}},
journal = {{Applied Optics}},
keywords = {{Atomic and Molecular Physics, and Optics, Engineering (miscellaneous), Electrical and Electronic Engineering}},
number = {{1}},
publisher = {{Optica Publishing Group}},
title = {{{Comparing transmission- and epi-BCARS: a round robin on solid-state materials}}},
doi = {{10.1364/ao.505374}},
volume = {{63}},
year = {{2024}},
}
@inproceedings{60023,
author = {{Wetter, Helene and Gao, Wenlong and Rehberg, Falk and Wingenbach, Jan and Schumacher, Stefan and Zentgraf, Thomas}},
booktitle = {{Proceedings of The 14th International Conference on Metamaterials, Photonic Crystals and Plasmonics}},
issn = {{2429-1390}},
location = {{Toyama, Japan}},
title = {{{Dielectric metasurface for wave-vector variant and circular polarization dependent transmission}}},
year = {{2024}},
}
@article{32101,
author = {{Weich, Tobias and Guedes Bonthonneau, Yannick and Guillarmou, Colin and Hilgert, Joachim}},
journal = {{J. Europ. Math. Soc.}},
number = {{8}},
pages = {{3085–3147}},
title = {{{Ruelle-Taylor resonances of Anosov actions}}},
doi = {{https://doi.org/10.4171/JEMS/1428}},
volume = {{27}},
year = {{2024}},
}
@article{57028,
abstract = {{Lithium niobate and lithium tantalate are among the most widespread materials for nonlinear, integrated photonics. Mixed crystals with arbitrary Nb–Ta ratios provide an additional degree of freedom to not only tune materials properties, such as the birefringence but also leverage the advantages of the singular compounds, for example, by combining the thermal stability of lithium tantalate with the larger nonlinear or piezoelectric constants of lithium niobate. Periodic poling allows to achieve phase-matching independent of waveguide geometry and is, therefore, one of the commonly used methods in integrated nonlinear optics. For mixed crystals, periodic poling has been challenging so far due to the lack of homogeneous, mono-domain crystals, which severely inhibit domain growth and nucleation. In this work, we investigate surface-near (<1μm depth) domain inversion on x-cut lithium niobate tantalate mixed crystals via electric field poling and lithographically structured electrodes. We find that naturally occurring head-to-head or tail-to-tail domain walls in the as-grown crystal inhibit domain inversion at a larger scale. However, periodic poling is possible if the gap size between the poling electrodes is of the same order of magnitude or smaller than the average size of naturally occurring domains. This work provides the basis for the nonlinear optical application of lithium niobate tantalate mixed crystals.}},
author = {{Bollmers, Laura and Babai-Hemati, Tobias and Koppitz, Boris and Eigner, Christof and Padberg, Laura and Rüsing, Michael and Eng, Lukas M. and Silberhorn, Christine}},
issn = {{0003-6951}},
journal = {{Applied Physics Letters}},
number = {{15}},
publisher = {{AIP Publishing}},
title = {{{Surface-near domain engineering in multi-domain x-cut lithium niobate tantalate mixed crystals}}},
doi = {{10.1063/5.0210972}},
volume = {{125}},
year = {{2024}},
}