[{"author":[{"first_name":"Christian","id":"44252","full_name":"Kießler, Christian","last_name":"Kießler"},{"id":"69553","full_name":"Kirsch, Michelle","last_name":"Kirsch","first_name":"Michelle"},{"first_name":"Sebastian","full_name":"Lengeling, Sebastian","id":"44373","last_name":"Lengeling"},{"last_name":"Herrmann","id":"216","full_name":"Herrmann, Harald","first_name":"Harald"},{"last_name":"Silberhorn","id":"26263","full_name":"Silberhorn, Christine","first_name":"Christine"}],"date_created":"2025-03-19T10:56:04Z","volume":4,"publisher":"Optica Publishing Group","date_updated":"2025-03-19T16:03:25Z","doi":"10.1364/optcon.557439","title":"SPDC single-photon source in Ti-indiffused diced ridge LiNbO3 waveguides","issue":"3","publication_status":"published","publication_identifier":{"issn":["2770-0208"]},"citation":{"ama":"Kießler C, Kirsch M, Lengeling S, Herrmann H, Silberhorn C. SPDC single-photon source in Ti-indiffused diced ridge LiNbO3 waveguides. Optics Continuum. 2025;4(3). doi:10.1364/optcon.557439","ieee":"C. Kießler, M. Kirsch, S. Lengeling, H. Herrmann, and C. Silberhorn, “SPDC single-photon source in Ti-indiffused diced ridge LiNbO3 waveguides,” Optics Continuum, vol. 4, no. 3, Art. no. 593, 2025, doi: 10.1364/optcon.557439.","chicago":"Kießler, Christian, Michelle Kirsch, Sebastian Lengeling, Harald Herrmann, and Christine Silberhorn. “SPDC Single-Photon Source in Ti-Indiffused Diced Ridge LiNbO3 Waveguides.” Optics Continuum 4, no. 3 (2025). https://doi.org/10.1364/optcon.557439.","bibtex":"@article{Kießler_Kirsch_Lengeling_Herrmann_Silberhorn_2025, title={SPDC single-photon source in Ti-indiffused diced ridge LiNbO3 waveguides}, volume={4}, DOI={10.1364/optcon.557439}, number={3593}, journal={Optics Continuum}, publisher={Optica Publishing Group}, author={Kießler, Christian and Kirsch, Michelle and Lengeling, Sebastian and Herrmann, Harald and Silberhorn, Christine}, year={2025} }","mla":"Kießler, Christian, et al. “SPDC Single-Photon Source in Ti-Indiffused Diced Ridge LiNbO3 Waveguides.” Optics Continuum, vol. 4, no. 3, 593, Optica Publishing Group, 2025, doi:10.1364/optcon.557439.","short":"C. Kießler, M. Kirsch, S. Lengeling, H. Herrmann, C. Silberhorn, Optics Continuum 4 (2025).","apa":"Kießler, C., Kirsch, M., Lengeling, S., Herrmann, H., & Silberhorn, C. (2025). SPDC single-photon source in Ti-indiffused diced ridge LiNbO3 waveguides. Optics Continuum, 4(3), Article 593. https://doi.org/10.1364/optcon.557439"},"intvolume":" 4","year":"2025","user_id":"216","department":[{"_id":"15"},{"_id":"623"},{"_id":"288"}],"_id":"59069","language":[{"iso":"eng"}],"article_number":"593","article_type":"original","type":"journal_article","publication":"Optics Continuum","status":"public","abstract":[{"lang":"eng","text":"Stable and bright single photon sources are key components for future quantum applications. A simple fabrication method is an important requirement for such sources. Here, we present a single photon source based on diced ridge waveguides in titanium indiffused LiNbO3. These waveguides can be easily fabricated by combining planar titanium in-diffusion without lithographic patterning and easy-to-handle precision dicing. Such devices have the potential to generate high single photon rates because ridge structures are typically less prone to the photorefractive effect. We achieve waveguide propagation losses <0.4dBcm and a SHG conversion efficiency of about 81%Wcm2. Harnessing a type-0 SPDC process to generate 1550 nm photons, we obtain a SPDC brightness of 3⋅1051s⋅mW⋅nm, with a heralding efficiency of ηh=45% (ηh,wg=77.5% for the waveguide itself excluded setup losses) and a heralded second-order correlation function of gh2(0)<0.003 at low pump powers."}]},{"title":"Cryogenic feedforward of a photonic quantum state","doi":"10.1364/optica.551287","date_updated":"2025-06-12T09:56:47Z","publisher":"Optica Publishing Group","date_created":"2025-06-04T18:34:16Z","author":[{"orcid":"0000-0003-0663-5587","last_name":"Thiele","full_name":"Thiele, Frederik","id":"50819","first_name":"Frederik"},{"full_name":"Lamberty, Niklas","id":"75307","last_name":"Lamberty","first_name":"Niklas"},{"first_name":"Thomas","full_name":"Hummel, Thomas","id":"83846","last_name":"Hummel","orcid":"0000-0001-8627-2119"},{"first_name":"Nina Amelie","last_name":"Lange","orcid":"0000-0001-6624-7098","id":"56843","full_name":"Lange, Nina Amelie"},{"last_name":"Procopio Peña","full_name":"Procopio Peña, Lorenzo Manuel","id":"105816","first_name":"Lorenzo Manuel"},{"last_name":"Barua","full_name":"Barua, Aishi","id":"104502","first_name":"Aishi"},{"first_name":"Sebastian","last_name":"Lengeling","full_name":"Lengeling, Sebastian","id":"44373"},{"last_name":"Quiring","full_name":"Quiring, Viktor","first_name":"Viktor"},{"id":"13244","full_name":"Eigner, Christof","last_name":"Eigner","orcid":"https://orcid.org/0000-0002-5693-3083","first_name":"Christof"},{"first_name":"Christine","full_name":"Silberhorn, Christine","id":"26263","last_name":"Silberhorn"},{"first_name":"Tim","full_name":"Bartley, Tim","id":"49683","last_name":"Bartley"}],"volume":12,"year":"2025","citation":{"apa":"Thiele, F., Lamberty, N., Hummel, T., Lange, N. A., Procopio Peña, L. M., Barua, A., Lengeling, S., Quiring, V., Eigner, C., Silberhorn, C., & Bartley, T. (2025). Cryogenic feedforward of a photonic quantum state. Optica, 12(5), Article 720. https://doi.org/10.1364/optica.551287","mla":"Thiele, Frederik, et al. “Cryogenic Feedforward of a Photonic Quantum State.” Optica, vol. 12, no. 5, 720, Optica Publishing Group, 2025, doi:10.1364/optica.551287.","short":"F. Thiele, N. Lamberty, T. Hummel, N.A. Lange, L.M. Procopio Peña, A. Barua, S. Lengeling, V. Quiring, C. Eigner, C. Silberhorn, T. Bartley, Optica 12 (2025).","bibtex":"@article{Thiele_Lamberty_Hummel_Lange_Procopio Peña_Barua_Lengeling_Quiring_Eigner_Silberhorn_et al._2025, title={Cryogenic feedforward of a photonic quantum state}, volume={12}, DOI={10.1364/optica.551287}, number={5720}, journal={Optica}, publisher={Optica Publishing Group}, author={Thiele, Frederik and Lamberty, Niklas and Hummel, Thomas and Lange, Nina Amelie and Procopio Peña, Lorenzo Manuel and Barua, Aishi and Lengeling, Sebastian and Quiring, Viktor and Eigner, Christof and Silberhorn, Christine and et al.}, year={2025} }","ama":"Thiele F, Lamberty N, Hummel T, et al. Cryogenic feedforward of a photonic quantum state. Optica. 2025;12(5). doi:10.1364/optica.551287","ieee":"F. Thiele et al., “Cryogenic feedforward of a photonic quantum state,” Optica, vol. 12, no. 5, Art. no. 720, 2025, doi: 10.1364/optica.551287.","chicago":"Thiele, Frederik, Niklas Lamberty, Thomas Hummel, Nina Amelie Lange, Lorenzo Manuel Procopio Peña, Aishi Barua, Sebastian Lengeling, et al. “Cryogenic Feedforward of a Photonic Quantum State.” Optica 12, no. 5 (2025). https://doi.org/10.1364/optica.551287."},"intvolume":" 12","publication_status":"published","publication_identifier":{"issn":["2334-2536"]},"issue":"5","article_number":"720","language":[{"iso":"eng"}],"_id":"60136","user_id":"56843","abstract":[{"text":"Modulation conditioned on measurements on entangled photonic quantum states is a cornerstone technology of optical quantum information processing. Performing this task with low latency requires combining single-photon-level detectors with both electronic logic processing and optical modulation in close proximity. Here, we demonstrate low-latency feedforward using a quasi-photon-number-resolved measurement on a quantum light source. Specifically, we use a multipixel superconducting nanowire single-photon detector, amplifier, logic, and an integrated electro-optic modulator in situ below 4 K. We modulate the signal mode of a spontaneous parametric down-conversion source, conditional on a photon-number measurement of the idler mode, with a total latency of (23±3)ns. Furthermore, we investigate the resulting change in the photon statistics. This represents an important benchmark for the fastest quantum photonic feedforward experiments comprising measurement, amplification, logic, and modulation. This has direct applications in quantum computing, communication, and simulation protocols.","lang":"eng"}],"status":"public","type":"journal_article","publication":"Optica"},{"status":"public","type":"journal_article","article_type":"original","article_number":"50451","project":[{"_id":"171","name":"TRR 142; TP C07: Hohlraum-verstärkte Parametrische Fluoreszenz mit zeitlicher Filterung unter Verwendung integrierter supraleitender Detektoren"}],"_id":"62269","user_id":"49683","department":[{"_id":"15"},{"_id":"623"},{"_id":"288"}],"citation":{"ama":"Lange NA, Lengeling S, Mues P, et al. Widely non-degenerate nonlinear frequency conversion in cryogenic titanium in-diffused lithium niobate waveguides. Optics Express. 2025;33(24). doi:10.1364/oe.578108","ieee":"N. A. Lange et al., “Widely non-degenerate nonlinear frequency conversion in cryogenic titanium in-diffused lithium niobate waveguides,” Optics Express, vol. 33, no. 24, Art. no. 50451, 2025, doi: 10.1364/oe.578108.","chicago":"Lange, Nina Amelie, Sebastian Lengeling, Philipp Mues, Viktor Quiring, Werner Ridder, Christof Eigner, Harald Herrmann, Christine Silberhorn, and Tim Bartley. “Widely Non-Degenerate Nonlinear Frequency Conversion in Cryogenic Titanium in-Diffused Lithium Niobate Waveguides.” Optics Express 33, no. 24 (2025). https://doi.org/10.1364/oe.578108.","apa":"Lange, N. A., Lengeling, S., Mues, P., Quiring, V., Ridder, W., Eigner, C., Herrmann, H., Silberhorn, C., & Bartley, T. (2025). Widely non-degenerate nonlinear frequency conversion in cryogenic titanium in-diffused lithium niobate waveguides. Optics Express, 33(24), Article 50451. https://doi.org/10.1364/oe.578108","short":"N.A. Lange, S. Lengeling, P. Mues, V. Quiring, W. Ridder, C. Eigner, H. Herrmann, C. Silberhorn, T. Bartley, Optics Express 33 (2025).","mla":"Lange, Nina Amelie, et al. “Widely Non-Degenerate Nonlinear Frequency Conversion in Cryogenic Titanium in-Diffused Lithium Niobate Waveguides.” Optics Express, vol. 33, no. 24, 50451, Optica Publishing Group, 2025, doi:10.1364/oe.578108.","bibtex":"@article{Lange_Lengeling_Mues_Quiring_Ridder_Eigner_Herrmann_Silberhorn_Bartley_2025, title={Widely non-degenerate nonlinear frequency conversion in cryogenic titanium in-diffused lithium niobate waveguides}, volume={33}, DOI={10.1364/oe.578108}, number={2450451}, journal={Optics Express}, publisher={Optica Publishing Group}, author={Lange, Nina Amelie and Lengeling, Sebastian and Mues, Philipp and Quiring, Viktor and Ridder, Werner and Eigner, Christof and Herrmann, Harald and Silberhorn, Christine and Bartley, Tim}, year={2025} }"},"intvolume":" 33","publication_status":"published","publication_identifier":{"issn":["1094-4087"]},"main_file_link":[{"open_access":"1"}],"doi":"10.1364/oe.578108","date_updated":"2025-12-12T12:13:45Z","oa":"1","author":[{"last_name":"Lange","orcid":"0000-0001-6624-7098","full_name":"Lange, Nina Amelie","id":"56843","first_name":"Nina Amelie"},{"full_name":"Lengeling, Sebastian","id":"44373","last_name":"Lengeling","first_name":"Sebastian"},{"id":"49772","full_name":"Mues, Philipp","orcid":"0000-0003-0643-7636","last_name":"Mues","first_name":"Philipp"},{"first_name":"Viktor","last_name":"Quiring","full_name":"Quiring, Viktor"},{"first_name":"Werner","last_name":"Ridder","id":"63574","full_name":"Ridder, Werner"},{"first_name":"Christof","full_name":"Eigner, Christof","id":"13244","orcid":"https://orcid.org/0000-0002-5693-3083","last_name":"Eigner"},{"first_name":"Harald","id":"216","full_name":"Herrmann, Harald","last_name":"Herrmann"},{"first_name":"Christine","last_name":"Silberhorn","id":"26263","full_name":"Silberhorn, Christine"},{"first_name":"Tim","last_name":"Bartley","id":"49683","full_name":"Bartley, Tim"}],"volume":33,"abstract":[{"lang":"eng","text":"The titanium in-diffused lithium niobate waveguide platform is well-established for reliable prototyping and packaging of many quantum photonic components at room temperature. Nevertheless, compatibility with certain quantum light sources and superconducting detectors requires operation under cryogenic conditions. We characterize alterations in phase-matching and mode guiding of a non-degenerate spontaneous parametric down-conversion process emitting around 1556 nm and 950 nm, under cryogenic conditions. Despite the effects of pyroelectricity and photorefraction, the spectral properties match our theoretical model. Nevertheless, these effects cause small but significant variations within and between cooling cycles. These measurements provide a first benchmark against which other nonlinear photonic integration platforms, such as thin-film lithium niobate, can be compared."}],"publication":"Optics Express","language":[{"iso":"eng"}],"year":"2025","issue":"24","title":"Widely non-degenerate nonlinear frequency conversion in cryogenic titanium in-diffused lithium niobate waveguides","publisher":"Optica Publishing Group","date_created":"2025-11-20T10:35:35Z"},{"publication":"Optics & Laser Technology","abstract":[{"text":"Lithium niobate (LiNbO3) is a widely used material with several desirable physical properties, such as high second-order nonlinear optical and strong electro-optical effects. Thus LiNbO3 is used for various applications such as electro-optic modulation or nonlinear frequency conversion and mixing. But LiNbO3 also exhibits a strong photorefractive effect, which limits the intensity of the optical fields involved. Various approaches to reduce the photorefractive effect have been investigated, such as increasing the temperature, doping the crystal or using different waveguide designs in LiNbO3. Here, we present an analysis of the approach to increase the photorefractive damage threshold by using different waveguide designs. Contrary to previous claims and investigations, our SHG measurements revealed no significant difference in resistance to photorefractive damage when comparing conventional Ti-doped channel waveguides and Ti-doped diced ridge waveguides in LiNbO3. Furthermore, we have investigated the effect of photorefractive cleaning and curing using a light field at 532 nm. Here, we observe a reduction in the photorefractive effect at room temperature during and after SHG measurements, which is an easy alternative to conventional approaches.","lang":"eng"}],"language":[{"iso":"eng"}],"quality_controlled":"1","year":"2025","publisher":"Elsevier BV","date_created":"2025-12-18T08:17:57Z","title":"Photorefraction and in-situ optical cleaning in various types of LiNbO3 waveguides","type":"journal_article","status":"public","_id":"63192","user_id":"69553","department":[{"_id":"288"},{"_id":"623"},{"_id":"15"}],"article_number":"114260","article_type":"original","publication_status":"published","publication_identifier":{"issn":["0030-3992"]},"citation":{"chicago":"Kirsch, Michelle, Christian Kießler, Sebastian Lengeling, Michael Stefszky, Christof Eigner, Harald Herrmann, and Christine Silberhorn. “Photorefraction and In-Situ Optical Cleaning in Various Types of LiNbO3 Waveguides.” Optics & Laser Technology 193 (2025). https://doi.org/10.1016/j.optlastec.2025.114260.","ieee":"M. Kirsch et al., “Photorefraction and in-situ optical cleaning in various types of LiNbO3 waveguides,” Optics & Laser Technology, vol. 193, Art. no. 114260, 2025, doi: 10.1016/j.optlastec.2025.114260.","ama":"Kirsch M, Kießler C, Lengeling S, et al. Photorefraction and in-situ optical cleaning in various types of LiNbO3 waveguides. Optics & Laser Technology. 2025;193. doi:10.1016/j.optlastec.2025.114260","apa":"Kirsch, M., Kießler, C., Lengeling, S., Stefszky, M., Eigner, C., Herrmann, H., & Silberhorn, C. (2025). Photorefraction and in-situ optical cleaning in various types of LiNbO3 waveguides. Optics & Laser Technology, 193, Article 114260. https://doi.org/10.1016/j.optlastec.2025.114260","bibtex":"@article{Kirsch_Kießler_Lengeling_Stefszky_Eigner_Herrmann_Silberhorn_2025, title={Photorefraction and in-situ optical cleaning in various types of LiNbO3 waveguides}, volume={193}, DOI={10.1016/j.optlastec.2025.114260}, number={114260}, journal={Optics & Laser Technology}, publisher={Elsevier BV}, author={Kirsch, Michelle and Kießler, Christian and Lengeling, Sebastian and Stefszky, Michael and Eigner, Christof and Herrmann, Harald and Silberhorn, Christine}, year={2025} }","mla":"Kirsch, Michelle, et al. “Photorefraction and In-Situ Optical Cleaning in Various Types of LiNbO3 Waveguides.” Optics & Laser Technology, vol. 193, 114260, Elsevier BV, 2025, doi:10.1016/j.optlastec.2025.114260.","short":"M. Kirsch, C. Kießler, S. Lengeling, M. Stefszky, C. Eigner, H. Herrmann, C. Silberhorn, Optics & Laser Technology 193 (2025)."},"intvolume":" 193","date_updated":"2025-12-18T08:27:13Z","oa":"1","author":[{"id":"69553","full_name":"Kirsch, Michelle","last_name":"Kirsch","first_name":"Michelle"},{"first_name":"Christian","full_name":"Kießler, Christian","id":"44252","last_name":"Kießler"},{"first_name":"Sebastian","id":"44373","full_name":"Lengeling, Sebastian","last_name":"Lengeling"},{"last_name":"Stefszky","id":"42777","full_name":"Stefszky, Michael","first_name":"Michael"},{"first_name":"Christof","orcid":"https://orcid.org/0000-0002-5693-3083","last_name":"Eigner","full_name":"Eigner, Christof","id":"13244"},{"full_name":"Herrmann, Harald","id":"216","last_name":"Herrmann","first_name":"Harald"},{"id":"26263","full_name":"Silberhorn, Christine","last_name":"Silberhorn","first_name":"Christine"}],"volume":193,"main_file_link":[{"url":"https://www.sciencedirect.com/science/article/pii/S0030399225018511?via%3Dihub","open_access":"1"}],"doi":"10.1016/j.optlastec.2025.114260"},{"status":"public","type":"journal_article","article_number":"074402","file_date_updated":"2025-07-10T06:43:34Z","_id":"60566","project":[{"name":"PC2: Computing Resources Provided by the Paderborn Center for Parallel Computing","_id":"52"},{"_id":"53","name":"TRR 142: TRR 142 - Maßgeschneiderte nichtlineare Photonik: Von grundlegenden Konzepten zu funktionellen Strukturen"},{"name":"TRR 142 - B: TRR 142 - Project Area B","_id":"55"},{"_id":"54","name":"TRR 142 - A: TRR 142 - Project Area A"},{"name":"TRR 142 - B07: TRR 142 - Polaronen-Einfluss auf die optischen Eigenschaften von Lithiumniobat (B07*)","_id":"168"},{"name":"TRR 142 - A11: TRR 142 - Subproject A11","_id":"166"}],"department":[{"_id":"15"},{"_id":"623"},{"_id":"295"},{"_id":"790"},{"_id":"288"},{"_id":"230"},{"_id":"429"},{"_id":"35"},{"_id":"170"},{"_id":"169"},{"_id":"27"}],"user_id":"22501","intvolume":" 9","citation":{"ieee":"A. Bocchini et al., “Mg dopants in lithium niobate: Defect models and impact on domain inversion,” Physical Review Materials, vol. 9, no. 7, Art. no. 074402, 2025, doi: 10.1103/5wz1-bjyr.","chicago":"Bocchini, Adriana, Michael Rüsing, Laura Bollmers, Sebastian Lengeling, Philipp Mues, Laura Padberg, Uwe Gerstmann, Christine Silberhorn, Christof Eigner, and Wolf Gero Schmidt. “Mg Dopants in Lithium Niobate: Defect Models and Impact on Domain Inversion.” Physical Review Materials 9, no. 7 (2025). https://doi.org/10.1103/5wz1-bjyr.","ama":"Bocchini A, Rüsing M, Bollmers L, et al. Mg dopants in lithium niobate: Defect models and impact on domain inversion. Physical Review Materials. 2025;9(7). doi:10.1103/5wz1-bjyr","apa":"Bocchini, A., Rüsing, M., Bollmers, L., Lengeling, S., Mues, P., Padberg, L., Gerstmann, U., Silberhorn, C., Eigner, C., & Schmidt, W. G. (2025). Mg dopants in lithium niobate: Defect models and impact on domain inversion. Physical Review Materials, 9(7), Article 074402. https://doi.org/10.1103/5wz1-bjyr","short":"A. Bocchini, M. Rüsing, L. Bollmers, S. Lengeling, P. Mues, L. Padberg, U. Gerstmann, C. Silberhorn, C. Eigner, W.G. Schmidt, Physical Review Materials 9 (2025).","bibtex":"@article{Bocchini_Rüsing_Bollmers_Lengeling_Mues_Padberg_Gerstmann_Silberhorn_Eigner_Schmidt_2025, title={Mg dopants in lithium niobate: Defect models and impact on domain inversion}, volume={9}, DOI={10.1103/5wz1-bjyr}, number={7074402}, journal={Physical Review Materials}, publisher={American Physical Society (APS)}, author={Bocchini, Adriana and Rüsing, Michael and Bollmers, Laura and Lengeling, Sebastian and Mues, Philipp and Padberg, Laura and Gerstmann, Uwe and Silberhorn, Christine and Eigner, Christof and Schmidt, Wolf Gero}, year={2025} }","mla":"Bocchini, Adriana, et al. “Mg Dopants in Lithium Niobate: Defect Models and Impact on Domain Inversion.” Physical Review Materials, vol. 9, no. 7, 074402, American Physical Society (APS), 2025, doi:10.1103/5wz1-bjyr."},"publication_identifier":{"issn":["2475-9953"]},"has_accepted_license":"1","publication_status":"published","doi":"10.1103/5wz1-bjyr","main_file_link":[{"url":"https://link.aps.org/doi/10.1103/5wz1-bjyr","open_access":"1"}],"oa":"1","date_updated":"2026-03-17T17:50:06Z","volume":9,"author":[{"full_name":"Bocchini, Adriana","id":"58349","orcid":"0000-0002-2134-3075","last_name":"Bocchini","first_name":"Adriana"},{"orcid":"0000-0003-4682-4577","last_name":"Rüsing","id":"22501","full_name":"Rüsing, Michael","first_name":"Michael"},{"last_name":"Bollmers","id":"61375","full_name":"Bollmers, Laura","first_name":"Laura"},{"full_name":"Lengeling, Sebastian","id":"44373","last_name":"Lengeling","first_name":"Sebastian"},{"id":"49772","full_name":"Mues, Philipp","orcid":"0000-0003-0643-7636","last_name":"Mues","first_name":"Philipp"},{"last_name":"Padberg","id":"40300","full_name":"Padberg, Laura","first_name":"Laura"},{"first_name":"Uwe","id":"171","full_name":"Gerstmann, Uwe","last_name":"Gerstmann","orcid":"0000-0002-4476-223X"},{"first_name":"Christine","full_name":"Silberhorn, Christine","id":"26263","last_name":"Silberhorn"},{"id":"13244","full_name":"Eigner, Christof","last_name":"Eigner","orcid":"https://orcid.org/0000-0002-5693-3083","first_name":"Christof"},{"last_name":"Schmidt","orcid":"0000-0002-2717-5076","id":"468","full_name":"Schmidt, Wolf Gero","first_name":"Wolf Gero"}],"file":[{"file_id":"60567","file_name":"Mg_dopants_LN_PRM.pdf","access_level":"open_access","file_size":4175120,"date_created":"2025-07-09T09:18:45Z","creator":"adrianab","date_updated":"2025-07-10T06:43:34Z","relation":"main_file","content_type":"application/pdf"}],"publication":"Physical Review Materials","ddc":["530"],"language":[{"iso":"eng"}],"year":"2025","issue":"7","title":"Mg dopants in lithium niobate: Defect models and impact on domain inversion","publisher":"American Physical Society (APS)","date_created":"2025-07-09T09:13:24Z"},{"publication_identifier":{"issn":["2633-4356"]},"publication_status":"published","issue":"1","year":"2024","intvolume":" 4","citation":{"bibtex":"@article{Thiele_Hummel_Lange_Dreher_Protte_Bruch_Lengeling_Herrmann_Eigner_Silberhorn_et al._2024, title={Pyroelectric influence on lithium niobate during the thermal transition for cryogenic integrated photonics}, volume={4}, DOI={10.1088/2633-4356/ad207d}, number={1015402}, journal={Materials for Quantum Technology}, publisher={IOP Publishing}, author={Thiele, Frederik and Hummel, Thomas and Lange, Nina Amelie and Dreher, Felix and Protte, Maximilian and Bruch, Felix vom and Lengeling, Sebastian and Herrmann, Harald and Eigner, Christof and Silberhorn, Christine and et al.}, year={2024} }","short":"F. Thiele, T. Hummel, N.A. Lange, F. Dreher, M. Protte, F. vom Bruch, S. Lengeling, H. Herrmann, C. Eigner, C. Silberhorn, T. Bartley, Materials for Quantum Technology 4 (2024).","mla":"Thiele, Frederik, et al. “Pyroelectric Influence on Lithium Niobate during the Thermal Transition for Cryogenic Integrated Photonics.” Materials for Quantum Technology, vol. 4, no. 1, 015402, IOP Publishing, 2024, doi:10.1088/2633-4356/ad207d.","apa":"Thiele, F., Hummel, T., Lange, N. A., Dreher, F., Protte, M., Bruch, F. vom, Lengeling, S., Herrmann, H., Eigner, C., Silberhorn, C., & Bartley, T. (2024). Pyroelectric influence on lithium niobate during the thermal transition for cryogenic integrated photonics. Materials for Quantum Technology, 4(1), Article 015402. https://doi.org/10.1088/2633-4356/ad207d","ama":"Thiele F, Hummel T, Lange NA, et al. Pyroelectric influence on lithium niobate during the thermal transition for cryogenic integrated photonics. Materials for Quantum Technology. 2024;4(1). doi:10.1088/2633-4356/ad207d","ieee":"F. Thiele et al., “Pyroelectric influence on lithium niobate during the thermal transition for cryogenic integrated photonics,” Materials for Quantum Technology, vol. 4, no. 1, Art. no. 015402, 2024, doi: 10.1088/2633-4356/ad207d.","chicago":"Thiele, Frederik, Thomas Hummel, Nina Amelie Lange, Felix Dreher, Maximilian Protte, Felix vom Bruch, Sebastian Lengeling, et al. “Pyroelectric Influence on Lithium Niobate during the Thermal Transition for Cryogenic Integrated Photonics.” Materials for Quantum Technology 4, no. 1 (2024). https://doi.org/10.1088/2633-4356/ad207d."},"date_updated":"2025-12-15T09:23:02Z","publisher":"IOP Publishing","volume":4,"date_created":"2024-02-16T07:56:44Z","author":[{"first_name":"Frederik","orcid":"0000-0003-0663-5587","last_name":"Thiele","id":"50819","full_name":"Thiele, Frederik"},{"id":"83846","full_name":"Hummel, Thomas","orcid":"0000-0001-8627-2119","last_name":"Hummel","first_name":"Thomas"},{"last_name":"Lange","orcid":"0000-0001-6624-7098","full_name":"Lange, Nina Amelie","id":"56843","first_name":"Nina Amelie"},{"full_name":"Dreher, Felix","last_name":"Dreher","first_name":"Felix"},{"last_name":"Protte","full_name":"Protte, Maximilian","first_name":"Maximilian"},{"first_name":"Felix vom","last_name":"Bruch","full_name":"Bruch, Felix vom"},{"last_name":"Lengeling","id":"44373","full_name":"Lengeling, Sebastian","first_name":"Sebastian"},{"last_name":"Herrmann","full_name":"Herrmann, Harald","id":"216","first_name":"Harald"},{"first_name":"Christof","orcid":"https://orcid.org/0000-0002-5693-3083","last_name":"Eigner","id":"13244","full_name":"Eigner, Christof"},{"last_name":"Silberhorn","full_name":"Silberhorn, Christine","id":"26263","first_name":"Christine"},{"last_name":"Bartley","id":"49683","full_name":"Bartley, Tim","first_name":"Tim"}],"title":"Pyroelectric influence on lithium niobate during the thermal transition for cryogenic integrated photonics","doi":"10.1088/2633-4356/ad207d","publication":"Materials for Quantum Technology","type":"journal_article","abstract":[{"lang":"eng","text":"Abstract\r\n Lithium niobate has emerged as a promising platform for integrated quantum optics, enabling efficient generation, manipulation, and detection of quantum states of light. However, integrating single-photon detectors requires cryogenic operating temperatures, since the best performing detectors are based on narrow superconducting wires. While previous studies have demonstrated the operation of quantum light sources and electro-optic modulators in LiNbO3 at cryogenic temperatures, the thermal transition between room temperature and cryogenic conditions introduces additional effects that can significantly influence device performance. In this paper, we investigate the generation of pyroelectric charges and their impact on the optical properties of lithium niobate waveguides when changing from room temperature to 25 K, and vice versa. We measure the generated pyroelectric charge flow and correlate this with fast changes in the birefringence acquired through the Sénarmont-method. Both electrical and optical influence of the pyroelectric effect occur predominantly at temperatures above 100 K."}],"status":"public","_id":"51356","project":[{"_id":"171","name":"TRR 142; TP C07: Hohlraum-verstärkte Parametrische Fluoreszenz mit zeitlicher Filterung unter Verwendung integrierter supraleitender Detektoren"}],"user_id":"56843","keyword":["General Earth and Planetary Sciences","General Environmental Science"],"article_number":"015402","language":[{"iso":"eng"}]},{"type":"journal_article","publication":"Optics Express","abstract":[{"text":"Quantum photonic processing via electro-optic components typically requires electronic links across different operation environments, especially when interfacing cryogenic components such as superconducting single photon detectors with room-temperature control and readout electronics. However, readout and driving electronics can introduce detrimental parasitic effects. Here we show an all-optical control and readout of a superconducting nanowire single photon detector (SNSPD), completely electrically decoupled from room temperature electronics. We provide the operation power for the superconducting detector via a cryogenic photodiode, and readout single photon detection signals via a cryogenic electro-optic modulator in the same cryostat. This method opens the possibility for control and readout of superconducting circuits, and feedforward for photonic quantum computing.","lang":"eng"}],"status":"public","_id":"48399","user_id":"50819","article_number":"32717","keyword":["Atomic and Molecular Physics","and Optics"],"language":[{"iso":"eng"}],"publication_status":"published","publication_identifier":{"issn":["1094-4087"]},"issue":"20","year":"2023","citation":{"short":"F. Thiele, T. Hummel, A.N. McCaughan, J. Brockmeier, M. Protte, V. Quiring, S. Lengeling, C. Eigner, C. Silberhorn, T. Bartley, Optics Express 31 (2023).","bibtex":"@article{Thiele_Hummel_McCaughan_Brockmeier_Protte_Quiring_Lengeling_Eigner_Silberhorn_Bartley_2023, title={All optical operation of a superconducting photonic interface}, volume={31}, DOI={10.1364/oe.492035}, number={2032717}, journal={Optics Express}, publisher={Optica Publishing Group}, author={Thiele, Frederik and Hummel, Thomas and McCaughan, Adam N. and Brockmeier, Julian and Protte, Maximilian and Quiring, Victor and Lengeling, Sebastian and Eigner, Christof and Silberhorn, Christine and Bartley, Tim}, year={2023} }","mla":"Thiele, Frederik, et al. “All Optical Operation of a Superconducting Photonic Interface.” Optics Express, vol. 31, no. 20, 32717, Optica Publishing Group, 2023, doi:10.1364/oe.492035.","apa":"Thiele, F., Hummel, T., McCaughan, A. N., Brockmeier, J., Protte, M., Quiring, V., Lengeling, S., Eigner, C., Silberhorn, C., & Bartley, T. (2023). All optical operation of a superconducting photonic interface. Optics Express, 31(20), Article 32717. https://doi.org/10.1364/oe.492035","chicago":"Thiele, Frederik, Thomas Hummel, Adam N. McCaughan, Julian Brockmeier, Maximilian Protte, Victor Quiring, Sebastian Lengeling, Christof Eigner, Christine Silberhorn, and Tim Bartley. “All Optical Operation of a Superconducting Photonic Interface.” Optics Express 31, no. 20 (2023). https://doi.org/10.1364/oe.492035.","ieee":"F. Thiele et al., “All optical operation of a superconducting photonic interface,” Optics Express, vol. 31, no. 20, Art. no. 32717, 2023, doi: 10.1364/oe.492035.","ama":"Thiele F, Hummel T, McCaughan AN, et al. All optical operation of a superconducting photonic interface. Optics Express. 2023;31(20). doi:10.1364/oe.492035"},"intvolume":" 31","publisher":"Optica Publishing Group","date_updated":"2023-11-27T08:43:33Z","date_created":"2023-10-24T06:43:16Z","author":[{"first_name":"Frederik","orcid":"0000-0003-0663-5587","last_name":"Thiele","full_name":"Thiele, Frederik","id":"50819"},{"first_name":"Thomas","last_name":"Hummel","id":"83846","full_name":"Hummel, Thomas"},{"first_name":"Adam N.","last_name":"McCaughan","full_name":"McCaughan, Adam N."},{"id":"44807","full_name":"Brockmeier, Julian","last_name":"Brockmeier","first_name":"Julian"},{"first_name":"Maximilian","full_name":"Protte, Maximilian","id":"46170","last_name":"Protte"},{"first_name":"Victor","full_name":"Quiring, Victor","last_name":"Quiring"},{"first_name":"Sebastian","last_name":"Lengeling","id":"44373","full_name":"Lengeling, Sebastian"},{"first_name":"Christof","orcid":"https://orcid.org/0000-0002-5693-3083","last_name":"Eigner","id":"13244","full_name":"Eigner, Christof"},{"last_name":"Silberhorn","id":"26263","full_name":"Silberhorn, Christine","first_name":"Christine"},{"last_name":"Bartley","full_name":"Bartley, Tim","id":"49683","first_name":"Tim"}],"volume":31,"title":"All optical operation of a superconducting photonic interface","doi":"10.1364/oe.492035"},{"author":[{"first_name":"Frederik","last_name":"Thiele","orcid":"0000-0003-0663-5587","full_name":"Thiele, Frederik","id":"50819"},{"first_name":"Felix","last_name":"vom Bruch","id":"71245","full_name":"vom Bruch, Felix"},{"last_name":"Brockmeier","full_name":"Brockmeier, Julian","id":"44807","first_name":"Julian"},{"first_name":"Maximilian","last_name":"Protte","full_name":"Protte, Maximilian","id":"46170"},{"last_name":"Hummel","full_name":"Hummel, Thomas","id":"83846","first_name":"Thomas"},{"first_name":"Raimund","full_name":"Ricken, Raimund","last_name":"Ricken"},{"first_name":"Viktor","full_name":"Quiring, Viktor","last_name":"Quiring"},{"first_name":"Sebastian","full_name":"Lengeling, Sebastian","id":"44373","last_name":"Lengeling"},{"first_name":"Harald","last_name":"Herrmann","full_name":"Herrmann, Harald","id":"216"},{"first_name":"Christof","last_name":"Eigner","orcid":"https://orcid.org/0000-0002-5693-3083","id":"13244","full_name":"Eigner, Christof"},{"last_name":"Silberhorn","id":"26263","full_name":"Silberhorn, Christine","first_name":"Christine"},{"first_name":"Tim","last_name":"Bartley","id":"49683","full_name":"Bartley, Tim"}],"volume":4,"date_updated":"2023-01-12T15:16:35Z","doi":"10.1088/2515-7647/ac6c63","publication_status":"published","publication_identifier":{"issn":["2515-7647"]},"citation":{"apa":"Thiele, F., vom Bruch, F., Brockmeier, J., Protte, M., Hummel, T., Ricken, R., Quiring, V., Lengeling, S., Herrmann, H., Eigner, C., Silberhorn, C., & Bartley, T. (2022). Cryogenic electro-optic modulation in titanium in-diffused lithium niobate waveguides. Journal of Physics: Photonics, 4(3), Article 034004. https://doi.org/10.1088/2515-7647/ac6c63","mla":"Thiele, Frederik, et al. “Cryogenic Electro-Optic Modulation in Titanium in-Diffused Lithium Niobate Waveguides.” Journal of Physics: Photonics, vol. 4, no. 3, 034004, IOP Publishing, 2022, doi:10.1088/2515-7647/ac6c63.","short":"F. Thiele, F. vom Bruch, J. Brockmeier, M. Protte, T. Hummel, R. Ricken, V. Quiring, S. Lengeling, H. Herrmann, C. Eigner, C. Silberhorn, T. Bartley, Journal of Physics: Photonics 4 (2022).","bibtex":"@article{Thiele_vom Bruch_Brockmeier_Protte_Hummel_Ricken_Quiring_Lengeling_Herrmann_Eigner_et al._2022, title={Cryogenic electro-optic modulation in titanium in-diffused lithium niobate waveguides}, volume={4}, DOI={10.1088/2515-7647/ac6c63}, number={3034004}, journal={Journal of Physics: Photonics}, publisher={IOP Publishing}, author={Thiele, Frederik and vom Bruch, Felix and Brockmeier, Julian and Protte, Maximilian and Hummel, Thomas and Ricken, Raimund and Quiring, Viktor and Lengeling, Sebastian and Herrmann, Harald and Eigner, Christof and et al.}, year={2022} }","ieee":"F. Thiele et al., “Cryogenic electro-optic modulation in titanium in-diffused lithium niobate waveguides,” Journal of Physics: Photonics, vol. 4, no. 3, Art. no. 034004, 2022, doi: 10.1088/2515-7647/ac6c63.","chicago":"Thiele, Frederik, Felix vom Bruch, Julian Brockmeier, Maximilian Protte, Thomas Hummel, Raimund Ricken, Viktor Quiring, et al. “Cryogenic Electro-Optic Modulation in Titanium in-Diffused Lithium Niobate Waveguides.” Journal of Physics: Photonics 4, no. 3 (2022). https://doi.org/10.1088/2515-7647/ac6c63.","ama":"Thiele F, vom Bruch F, Brockmeier J, et al. Cryogenic electro-optic modulation in titanium in-diffused lithium niobate waveguides. Journal of Physics: Photonics. 2022;4(3). doi:10.1088/2515-7647/ac6c63"},"intvolume":" 4","user_id":"83846","department":[{"_id":"15"},{"_id":"230"},{"_id":"623"}],"_id":"33672","article_number":"034004","type":"journal_article","status":"public","date_created":"2022-10-11T07:14:40Z","publisher":"IOP Publishing","title":"Cryogenic electro-optic modulation in titanium in-diffused lithium niobate waveguides","issue":"3","year":"2022","language":[{"iso":"eng"}],"keyword":["Electrical and Electronic Engineering","Atomic and Molecular Physics","and Optics","Electronic","Optical and Magnetic Materials"],"publication":"Journal of Physics: Photonics","abstract":[{"lang":"eng","text":"Abstract\r\n Lithium niobate is a promising platform for integrated quantum optics. In this platform, we aim to efficiently manipulate and detect quantum states by combining superconducting single photon detectors and modulators. The cryogenic operation of a superconducting single photon detector dictates the optimisation of the electro-optic modulators under the same operating conditions. To that end, we characterise a phase modulator, directional coupler, and polarisation converter at both ambient and cryogenic temperatures. The operation voltage \r\n \r\n \r\n \r\n V\r\n \r\n π\r\n \r\n /\r\n \r\n 2\r\n \r\n \r\n \r\n \r\n of these modulators increases, due to the decrease in the electro-optic effect, by 74% for the phase modulator, 84% for the directional coupler and 35% for the polarisation converter below 8.5\r\n \r\n \r\n \r\n K\r\n \r\n \r\n \r\n . The phase modulator preserves its broadband nature and modulates light in the characterised wavelength range. The unbiased bar state of the directional coupler changed by a wavelength shift of 85\r\n \r\n \r\n \r\n n\r\n m\r\n \r\n \r\n \r\n while cooling the device down to 5\r\n \r\n \r\n \r\n K\r\n \r\n \r\n \r\n . The polarisation converter uses periodic poling to phasematch the two orthogonal polarisations. The phasematched wavelength of the utilised poling changes by 112\r\n \r\n \r\n \r\n n\r\n m\r\n \r\n \r\n \r\n when cooling to 5\r\n \r\n \r\n \r\n K\r\n \r\n \r\n \r\n ."}]},{"series_title":"Quantum Photonic Devices - SPIE","user_id":"49063","department":[{"_id":"15"},{"_id":"170"},{"_id":"293"},{"_id":"288"},{"_id":"230"},{"_id":"429"}],"project":[{"_id":"53","name":"TRR 142"},{"_id":"56","name":"TRR 142 - Project Area C"},{"name":"TRR 142 - Subproject C2","_id":"72"}],"_id":"13903","type":"conference","status":"public","editor":[{"full_name":"Agio, Mario","last_name":"Agio","first_name":"Mario"},{"full_name":"Srinivasan, Kartik","last_name":"Srinivasan","first_name":"Kartik"},{"first_name":"Cesare","last_name":"Soci","full_name":"Soci, Cesare"}],"author":[{"first_name":"Jan Philipp","last_name":"Höpker","id":"33913","full_name":"Höpker, Jan Philipp"},{"first_name":"Moritz","last_name":"Bartnick","full_name":"Bartnick, Moritz"},{"full_name":"Meyer-Scott, Evan","last_name":"Meyer-Scott","first_name":"Evan"},{"full_name":"Thiele, Frederik","last_name":"Thiele","first_name":"Frederik"},{"first_name":"Torsten","full_name":"Meier, Torsten","id":"344","last_name":"Meier","orcid":"0000-0001-8864-2072"},{"id":"49683","full_name":"Bartley, Tim","last_name":"Bartley","first_name":"Tim"},{"first_name":"Stephan","full_name":"Krapick, Stephan","last_name":"Krapick"},{"full_name":"Montaut, Nicola M.","last_name":"Montaut","first_name":"Nicola M."},{"full_name":"Santandrea, Matteo","id":"55095","orcid":"0000-0001-5718-358X","last_name":"Santandrea","first_name":"Matteo"},{"last_name":"Herrmann","id":"216","full_name":"Herrmann, Harald","first_name":"Harald"},{"first_name":"Sebastian","last_name":"Lengeling","full_name":"Lengeling, Sebastian","id":"44373"},{"full_name":"Ricken, Raimund","last_name":"Ricken","first_name":"Raimund"},{"first_name":"Viktor","last_name":"Quiring","full_name":"Quiring, Viktor"},{"first_name":"Adriana E.","last_name":"Lita","full_name":"Lita, Adriana E."},{"first_name":"Varun B.","full_name":"Verma, Varun B.","last_name":"Verma"},{"last_name":"Gerrits","full_name":"Gerrits, Thomas","first_name":"Thomas"},{"first_name":"Sae Woo","last_name":"Nam","full_name":"Nam, Sae Woo"},{"full_name":"Silberhorn, Christine","id":"26263","last_name":"Silberhorn","first_name":"Christine"}],"volume":10358,"date_updated":"2023-04-16T20:59:06Z","doi":"10.1117/12.2273388","publication_status":"published","publication_identifier":{"isbn":["9781510611733","9781510611740"]},"citation":{"bibtex":"@inproceedings{Höpker_Bartnick_Meyer-Scott_Thiele_Meier_Bartley_Krapick_Montaut_Santandrea_Herrmann_et al._2017, series={Quantum Photonic Devices - SPIE}, title={Towards integrated superconducting detectors on lithium niobate waveguides}, volume={10358}, DOI={10.1117/12.2273388}, booktitle={Quantum Photonic Devices}, publisher={SPIE}, author={Höpker, Jan Philipp and Bartnick, Moritz and Meyer-Scott, Evan and Thiele, Frederik and Meier, Torsten and Bartley, Tim and Krapick, Stephan and Montaut, Nicola M. and Santandrea, Matteo and Herrmann, Harald and et al.}, editor={Agio, Mario and Srinivasan, Kartik and Soci, Cesare}, year={2017}, pages={1035809}, collection={Quantum Photonic Devices - SPIE} }","mla":"Höpker, Jan Philipp, et al. “Towards Integrated Superconducting Detectors on Lithium Niobate Waveguides.” Quantum Photonic Devices, edited by Mario Agio et al., vol. 10358, SPIE, 2017, p. 1035809, doi:10.1117/12.2273388.","short":"J.P. Höpker, M. Bartnick, E. Meyer-Scott, F. Thiele, T. Meier, T. Bartley, S. Krapick, N.M. Montaut, M. Santandrea, H. Herrmann, S. Lengeling, R. Ricken, V. Quiring, A.E. Lita, V.B. Verma, T. Gerrits, S.W. Nam, C. Silberhorn, in: M. Agio, K. Srinivasan, C. Soci (Eds.), Quantum Photonic Devices, SPIE, 2017, p. 1035809.","apa":"Höpker, J. P., Bartnick, M., Meyer-Scott, E., Thiele, F., Meier, T., Bartley, T., Krapick, S., Montaut, N. M., Santandrea, M., Herrmann, H., Lengeling, S., Ricken, R., Quiring, V., Lita, A. E., Verma, V. B., Gerrits, T., Nam, S. W., & Silberhorn, C. (2017). Towards integrated superconducting detectors on lithium niobate waveguides. In M. Agio, K. Srinivasan, & C. Soci (Eds.), Quantum Photonic Devices (Vol. 10358, p. 1035809). SPIE. https://doi.org/10.1117/12.2273388","ama":"Höpker JP, Bartnick M, Meyer-Scott E, et al. Towards integrated superconducting detectors on lithium niobate waveguides. In: Agio M, Srinivasan K, Soci C, eds. Quantum Photonic Devices. Vol 10358. Quantum Photonic Devices - SPIE. SPIE; 2017:1035809. doi:10.1117/12.2273388","chicago":"Höpker, Jan Philipp, Moritz Bartnick, Evan Meyer-Scott, Frederik Thiele, Torsten Meier, Tim Bartley, Stephan Krapick, et al. “Towards Integrated Superconducting Detectors on Lithium Niobate Waveguides.” In Quantum Photonic Devices, edited by Mario Agio, Kartik Srinivasan, and Cesare Soci, 10358:1035809. Quantum Photonic Devices - SPIE. SPIE, 2017. https://doi.org/10.1117/12.2273388.","ieee":"J. P. Höpker et al., “Towards integrated superconducting detectors on lithium niobate waveguides,” in Quantum Photonic Devices, 2017, vol. 10358, p. 1035809, doi: 10.1117/12.2273388."},"intvolume":" 10358","page":"1035809","language":[{"iso":"eng"}],"publication":"Quantum Photonic Devices","date_created":"2019-10-18T08:01:45Z","publisher":"SPIE","title":"Towards integrated superconducting detectors on lithium niobate waveguides","year":"2017"}]