[{"volume":11,"publication_identifier":{"eissn":["2195-1071"]},"isi":1,"publisher":"Wiley","intvolume":" 11","external_id":{"arxiv":["2211.08755"],"isi":["000963866700001"]},"publication":"Advanced Optical Materials","publication_status":"published","language":[{"iso":"eng"}],"day":"04","date_updated":"2023-10-04T11:15:17Z","quality_controlled":"1","_id":"12836","arxiv":1,"issue":"13","month":"07","doi":"10.1002/adom.202202631","article_processing_charge":"No","date_published":"2023-07-04T00:00:00Z","type":"journal_article","user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","main_file_link":[{"open_access":"1","url":"https://doi.org/10.48550/arXiv.2211.08755"}],"status":"public","date_created":"2023-04-16T22:01:09Z","abstract":[{"lang":"eng","text":"Coherent control and manipulation of quantum degrees of freedom such as spins forms the basis of emerging quantum technologies. In this context, the robust valley degree of freedom and the associated valley pseudospin found in two-dimensional transition metal dichalcogenides is a highly attractive platform. Valley polarization and coherent superposition of valley states have been observed in these systems even up to room temperature. Control of valley coherence is an important building block for the implementation of valley qubit. Large magnetic fields or high-power lasers have been used in the past to demonstrate the control (initialization and rotation) of the valley coherent states. Here, the control of layer–valley coherence via strong coupling of valley excitons in bilayer WS2 to microcavity photons is demonstrated by exploiting the pseudomagnetic field arising in optical cavities owing to the transverse electric–transverse magnetic (TE–TM)mode splitting. The use of photonic structures to generate pseudomagnetic fields which can be used to manipulate exciton-polaritons presents an attractive approach to control optical responses without the need for large magnets or high-intensity optical pump powers."}],"acknowledgement":"The authors acknowledge insightful discussions with Prof. Wang Yao and graphics by Rezlind Bushati. M.K. and N.Y. acknowledge support from NSF grants NSF DMR-1709996 and NSF OMA 1936276. S.G. was supported by the Army Research Office Multidisciplinary University Research Initiative program (W911NF-17-1-0312) and V.M.M. by the Army Research Office grant (W911NF-22-1-0091). K.M acknowledges the SPARC program that supported his collaboration with the CUNY team. The authors acknowledge the Nanofabrication facility at the CUNY Advanced Science Research Center where the cavity devices were fabricated.","department":[{"_id":"MiLe"}],"author":[{"last_name":"Khatoniar","full_name":"Khatoniar, Mandeep","first_name":"Mandeep"},{"last_name":"Yama","full_name":"Yama, Nicholas","first_name":"Nicholas"},{"last_name":"Ghazaryan","full_name":"Ghazaryan, Areg","id":"4AF46FD6-F248-11E8-B48F-1D18A9856A87","first_name":"Areg","orcid":"0000-0001-9666-3543"},{"first_name":"Sriram","full_name":"Guddala, Sriram","last_name":"Guddala"},{"full_name":"Ghaemi, Pouyan","last_name":"Ghaemi","first_name":"Pouyan"},{"full_name":"Majumdar, Kausik","last_name":"Majumdar","first_name":"Kausik"},{"first_name":"Vinod","last_name":"Menon","full_name":"Menon, Vinod"}],"citation":{"mla":"Khatoniar, Mandeep, et al. “Optical Manipulation of Layer–Valley Coherence via Strong Exciton–Photon Coupling in Microcavities.” Advanced Optical Materials, vol. 11, no. 13, 2202631, Wiley, 2023, doi:10.1002/adom.202202631.","chicago":"Khatoniar, Mandeep, Nicholas Yama, Areg Ghazaryan, Sriram Guddala, Pouyan Ghaemi, Kausik Majumdar, and Vinod Menon. “Optical Manipulation of Layer–Valley Coherence via Strong Exciton–Photon Coupling in Microcavities.” Advanced Optical Materials. Wiley, 2023. https://doi.org/10.1002/adom.202202631.","ama":"Khatoniar M, Yama N, Ghazaryan A, et al. Optical manipulation of Layer–Valley coherence via strong exciton–photon coupling in microcavities. Advanced Optical Materials. 2023;11(13). doi:10.1002/adom.202202631","ista":"Khatoniar M, Yama N, Ghazaryan A, Guddala S, Ghaemi P, Majumdar K, Menon V. 2023. Optical manipulation of Layer–Valley coherence via strong exciton–photon coupling in microcavities. Advanced Optical Materials. 11(13), 2202631.","short":"M. Khatoniar, N. Yama, A. Ghazaryan, S. Guddala, P. Ghaemi, K. Majumdar, V. Menon, Advanced Optical Materials 11 (2023).","ieee":"M. Khatoniar et al., “Optical manipulation of Layer–Valley coherence via strong exciton–photon coupling in microcavities,” Advanced Optical Materials, vol. 11, no. 13. Wiley, 2023.","apa":"Khatoniar, M., Yama, N., Ghazaryan, A., Guddala, S., Ghaemi, P., Majumdar, K., & Menon, V. (2023). Optical manipulation of Layer–Valley coherence via strong exciton–photon coupling in microcavities. Advanced Optical Materials. Wiley. https://doi.org/10.1002/adom.202202631"},"title":"Optical manipulation of Layer–Valley coherence via strong exciton–photon coupling in microcavities","article_type":"original","oa_version":"Preprint","scopus_import":"1","oa":1,"year":"2023","article_number":"2202631"},{"tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","short":"CC BY (4.0)","image":"/images/cc_by.png","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)"},"abstract":[{"lang":"eng","text":"Converting ionizing radiation into visible light is essential in a wide range of fundamental and industrial applications, such as electromagnetic calorimeters in high-energy particle detectors, electron detectors, image intensifiers, and X-ray imaging. These different areas of technology all rely on scintillators or phosphors, i.e., materials that emit light upon bombardment by high-energy particles. In all cases, the emission is through spontaneous emission. The fundamental nature of spontaneous emission poses limitations on all these technologies, imposing an intrinsic trade-off between efficiency and resolution in all imaging applications: thicker phosphors are more efficient due to their greater stopping power, which however comes at the expense of image blurring due to light spread inside the thicker phosphors. Here, the concept of inverse-designed nanophotonic scintillators is proposed, which can overcome the trade-off between resolution and efficiency by reshaping the intrinsic spontaneous emission. To exemplify the concept, multilayer phosphor nanostructures are designed and these nanostructures are compared to state-of-the-art phosphor screens in image intensifiers, showing a threefold resolution enhancement simultaneous with a threefold efficiency enhancement. The enabling concept is applying the ubiquitous Purcell effect for the first time in a new context—for improving image resolution. Looking forward, this approach directly applies to a wide range of technologies, including X-ray imaging applications."}],"date_created":"2026-03-30T12:22:47Z","license":"https://creativecommons.org/licenses/by/4.0/","title":"Enhanced imaging using inverse design of nanophotonic scintillators","citation":{"mla":"Shultzman, Avner, et al. “Enhanced Imaging Using Inverse Design of Nanophotonic Scintillators.” Advanced Optical Materials, vol. 11, no. 8, 2202318, Wiley, 2023, doi:10.1002/adom.202202318.","short":"A. Shultzman, O. Segal, Y. Kurman, C. Roques-Carmes, I. Kaminer, Advanced Optical Materials 11 (2023).","ista":"Shultzman A, Segal O, Kurman Y, Roques-Carmes C, Kaminer I. 2023. Enhanced imaging using inverse design of nanophotonic scintillators. Advanced Optical Materials. 11(8), 2202318.","ama":"Shultzman A, Segal O, Kurman Y, Roques-Carmes C, Kaminer I. Enhanced imaging using inverse design of nanophotonic scintillators. Advanced Optical Materials. 2023;11(8). doi:10.1002/adom.202202318","chicago":"Shultzman, Avner, Ohad Segal, Yaniv Kurman, Charles Roques-Carmes, and Ido Kaminer. “Enhanced Imaging Using Inverse Design of Nanophotonic Scintillators.” Advanced Optical Materials. Wiley, 2023. https://doi.org/10.1002/adom.202202318.","ieee":"A. Shultzman, O. Segal, Y. Kurman, C. Roques-Carmes, and I. Kaminer, “Enhanced imaging using inverse design of nanophotonic scintillators,” Advanced Optical Materials, vol. 11, no. 8. Wiley, 2023.","apa":"Shultzman, A., Segal, O., Kurman, Y., Roques-Carmes, C., & Kaminer, I. (2023). Enhanced imaging using inverse design of nanophotonic scintillators. Advanced Optical Materials. Wiley. https://doi.org/10.1002/adom.202202318"},"author":[{"full_name":"Shultzman, Avner","last_name":"Shultzman","first_name":"Avner"},{"last_name":"Segal","full_name":"Segal, Ohad","first_name":"Ohad"},{"full_name":"Kurman, Yaniv","last_name":"Kurman","first_name":"Yaniv"},{"id":"e2e68fc9-6505-11ef-a541-eb4e72cc3e82","first_name":"Charles","last_name":"Roques-Carmes","full_name":"Roques-Carmes, Charles"},{"first_name":"Ido","last_name":"Kaminer","full_name":"Kaminer, Ido"}],"extern":"1","article_type":"original","scopus_import":"1","oa_version":"Published Version","oa":1,"article_number":"2202318","OA_place":"publisher","year":"2023","publication_identifier":{"eissn":["2195-1071"]},"volume":11,"publisher":"Wiley","intvolume":" 11","publication_status":"published","publication":"Advanced Optical Materials","day":"17","language":[{"iso":"eng"}],"_id":"21511","date_updated":"2026-04-27T10:38:22Z","quality_controlled":"1","doi":"10.1002/adom.202202318","month":"02","ddc":["530"],"issue":"8","article_processing_charge":"No","main_file_link":[{"open_access":"1","url":"https://doi.org/10.1002/adom.202202318"}],"status":"public","user_id":"ba8df636-2132-11f1-aed0-ed93e2281fdd","type":"journal_article","date_published":"2023-02-17T00:00:00Z","OA_type":"hybrid"},{"oa_version":"None","scopus_import":"1","year":"2016","date_created":"2023-08-01T09:42:49Z","abstract":[{"text":"Come on in, the water's fine! Non-photoresponsive nanoparticles can be reversibly assembled using light by placing them in an aqueous solution of a photo­acid. Upon exposure to visible light, the photoacid reduces the pH of the solution, which induces attractive interactions between the nanoparticles. In the dark, the resulting nanoparticle aggregates spontaneously disassemble. The process can be repeated many times.","lang":"eng"}],"page":"1373-1377","author":[{"first_name":"Dipak","full_name":"Samanta, Dipak","last_name":"Samanta"},{"id":"8e84690e-1e48-11ed-a02b-a1e6fb8bb53b","first_name":"Rafal","full_name":"Klajn, Rafal","last_name":"Klajn"}],"citation":{"ieee":"D. Samanta and R. Klajn, “Aqueous light-controlled self-assembly of nanoparticles,” Advanced Optical Materials, vol. 4, no. 9. Wiley, pp. 1373–1377, 2016.","apa":"Samanta, D., & Klajn, R. (2016). Aqueous light-controlled self-assembly of nanoparticles. Advanced Optical Materials. Wiley. https://doi.org/10.1002/adom.201600364","mla":"Samanta, Dipak, and Rafal Klajn. “Aqueous Light-Controlled Self-Assembly of Nanoparticles.” Advanced Optical Materials, vol. 4, no. 9, Wiley, 2016, pp. 1373–77, doi:10.1002/adom.201600364.","ama":"Samanta D, Klajn R. Aqueous light-controlled self-assembly of nanoparticles. Advanced Optical Materials. 2016;4(9):1373-1377. doi:10.1002/adom.201600364","chicago":"Samanta, Dipak, and Rafal Klajn. “Aqueous Light-Controlled Self-Assembly of Nanoparticles.” Advanced Optical Materials. Wiley, 2016. https://doi.org/10.1002/adom.201600364.","ista":"Samanta D, Klajn R. 2016. Aqueous light-controlled self-assembly of nanoparticles. Advanced Optical Materials. 4(9), 1373–1377.","short":"D. Samanta, R. Klajn, Advanced Optical Materials 4 (2016) 1373–1377."},"title":"Aqueous light-controlled self-assembly of nanoparticles","article_type":"original","extern":"1","date_updated":"2024-10-14T12:16:34Z","quality_controlled":"1","_id":"13387","issue":"9","doi":"10.1002/adom.201600364","month":"09","article_processing_charge":"No","date_published":"2016-09-01T00:00:00Z","type":"journal_article","user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","status":"public","volume":4,"publication_identifier":{"eissn":["2195-1071"]},"keyword":["Atomic and Molecular Physics","and Optics","Electronic","Optical and Magnetic Materials"],"intvolume":" 4","publisher":"Wiley","publication":"Advanced Optical Materials","publication_status":"published","language":[{"iso":"eng"}],"day":"01"}]