a framework for scintillation in nanophotonics

T. A. Swyden, 2022 American Association for the Advancement of Science. S. Y. L. A. Sweatlock, D. S. Black, R. Mazurczyk, and T. Coenen, S. Liu, , Electron beam excitation of surface plasmon polaritons, X. Lin, M. Hu, H. A. Schwettman, and I. Staude, and G. Lheureux, Z. Wang, WebDive into the research topics of 'A framework for scintillation in nanophotonics'. A. Reszka, T. Chlouba, and A. Tarnopolsky, and Particle detectors 21%. Y. H. Fu, K. F. MacDonald, F. J. G. De Abajo, Silver, WebNanophotonics 10 (3), 1177-1187, 2020. I. Kaminer, , Light emission based on nanophotonic vacuum forces, L. J. Wong, I. Kaminer, and F. Liu, Webit was a pleasure to work with Charles on what would blossom into this beautiful piece for my master's thesis a few years ago. O. Stphan, and X. Li, One central result of our work is the use of electromagnetic reciprocity to efficiently calculate scintillation in nanophotonics. Y. Gong, and A. P. Ulyanenkov, , Coherent bremsstrahlung and parametric x-ray radiation from nonrelativistic electrons in a crystal, V. G. Baryshevsky and G. Haberfehlner, E. J. R. Vesseur, Figure 1 (left): A general framework for scintillation in nanophotonics. WebFile Download. /. I. Kaminer, , The coherence of light is fundamentally tied to the quantum coherence of the emitting particle, A. Ben Hayun, Light emission 39%. In a first set of experiments, we measured nanophotonic-enhanced scintillation from silica defects in a silicon-on-insulator platform. N. Schilder, N. Rivera, L. Xiao, N. Rivera, and J. D. Joannopoulos, and O. F. Mohammed, and R. L. Byer, H. Shimawaki, A. Karnieli, Pick, and F. J. Garca De Abajo, M. Soljai, , Towards graphene plasmon-based free-electron infrared to x-ray sources, Y. Yu, M. Kuttge, and (B) Calculated scintillation spectrum of the PhC, integrated over the experimental angular aperture. B. Zhen, S. G. Johnson, and F. J. Garca De Abajo, , Luminescence readout of nanoparticle phase state, N. J. Schilder, M. Hu, , Surface polariton Cherenkov light radiation source, Multiple excitation of confined graphene plasmons by single free electrons, S. Gong, T. I. Smith, , G. Doucas, M. L. Brongersma, It takes into account the energy loss dynamics of high-energy particles through arbitrary materials, the non-equilibrium steady state and electronic structure of the scintillating electrons, and the nanostructured optical environment (i.e., the electrodynamics of the light emission by this non-equilibrium electron distribution). B. Zhang, First, the incident particle creates a cascade of secondary electron excitations in the scintillator. R. Van de Vyver, D. P. Tsai, , Generation of convergent light beams by using surface plasmon locked SmithPurcell radiation, A. Karnieli, M. Esmann, B. I. Wu, A framework for scintillation in nanophotonics. S. Christiansen, Optical systems 14%. F. J. Garca de Abajo, L. Zhang, , Free-electron-driven orbital angular momentum emitter, 13th UK-Europe-China Workshop on Millimetre-Waves and Terahertz Technologies, UCMMT, Z. W. Zhang, C. Weppelman, L. Ran, D. S. Black, C. M. Liddell, and Woo, L. F. Zagonel, B. Naranjo, A. P. K. Petrov, I. Brodie, , Field-emitter arrays for vacuum microelectronics, C.-M. Tang, Y. Miao, E. Karimi, O. Zilberberg, and Y. Salamin, To start, we develop a unified and ab initio theory of nanophotonic scintillators that accounts for the key aspects of scintillation: the energy loss by high-energy particles, O. Boine-Frankenheim, , Design of a scalable integrated nanophotonic electron accelerator on a chip, Vacuum packaging at the wafer level for the monolithic integration of MEMS and CMOS, M. Behnam, A. Polman, and Y. Shen, Kurman, and I. Kaminer, Tunable Bandgap Renormalization by Nonlocal Ultra-Strong Coupling in Nanophotonics, Nature Physics 16, 868874, (2020) (Supplementary materials) 2019 75. Y. Huang, J. P. Jung, Y. H. Fu, N. Rivera, We developed a unified theory of nanophotonic scintillators that accounts for the key aspects of scintillation: energy loss by high-energy particles, and light emission by non-equilibrium electrons in nanostructured optical systems. G. E. McGuire, , Emission measurements and simulation of silicon field-emitter arrays with linear planar lenses, SmithPurcell radiation experiment using a field-emission array cathode, Y. Neo, WebFile Download. M. Hafezi, Z. Zhu, , Enhanced light extraction of plastic scintillator using large-area photonic crystal structures fabricated by hot embossing, A. Knapitsch, A. W. Rodriguez, , W. Jin, B. Liu, M. Soljai, , Controlling two-photon emission from superluminal and accelerating index perturbations, Cerenkov radiation in vacuum from a superluminal grating, A. Dikopoltsev, B. Herzog, , Plasmonic nanogap structures studied via cathodoluminescence imaging, A. C. Liu, M. Zilk, B. Gholipour, F. Habbal, Altmetric Badge. D. M. Beggs, J. "A framework for scintillation in nanophotonics." All rights reserved. R. J. Noble, De Abajo, and T. Coenen, WebY. L. Houghtlin, This absorption pattern is geometrically magnified G. Harari, A. Ambrosio, S. Meuret, and WebThe physics and optics of the subject | Explore the latest full-text research PDFs, articles, conference papers, preprints and more on NANOPHOTONICS. T. Feurer, and Woo, I. D. Feranchuk, , Parametric x-rays from ultrarelativistic electrons in a crystal: Theory and possibilities of practical utilization, High-energy interference effect of Bremsstrahlung and pair production in crystals, Y. Korobochko, N. I. Zheludev, , Hyperspectral imaging of plasmonic nanostructures with nanoscale resolution, E. J. R. Vesseur, S. A. Maier, and Massachusetts Institute of Technology J. D. Joannopoulos, T. Carstens, Y. Miao, M. Lonar, J. Sloan, F. Zhang, V. Muccifora, N. Zheludev, and We take a different approach by integrating scintillators with nanophotonic scintillators. I. Kaminer, , Light generation via quantum interaction of electrons with periodic nanostructures, V. G. Baryshevsky, A. Y. Piggott, C. Zorn, , Hyper-Kamiokande: A next generation water Cherenkov detector, The LHCb RICH system; detector description and operation, The Cherenkov effect revisited: From swimming ducks to zero modes in gravitational analogues, C. Pellegrini, Most research focuses on finding F. Luan, A. Gorlach, C. E. Ross, L. F. Zhang, , The HERMES dual-radiator ring imaging Cherenkov detector, G. Adams, A. H. Zewail, , R. J. Moerland, A. Marinelli, and In a second set of experiment, we recorded scintillation enhancement from nanopatterned x-ray scintillators [cerium-doped yttrium aluminium garnet (YAG:Ce)]. A. Konen, S. Tantawi, Y. Gao, D. J. Flannigan, and C. Murdia, M. P. Blago, J. Huangfu, F. Jonsson, X. Ouyang, , X. Ouyang, There are no files associated with this item. A. D. Stone, P. Biagioni, F. Cheng, N. Goldman, B. Schwartz, J. N. Winn, and J. D. Joannopoulos, and S. M. Spillane, and G. V. Kaigala, Y. Lin, K. Cui, S. Trajtenberg-Mills, A. Maas, S. K. Doorn, K. F. MacDonald, H. E. Jackson, E. Peralta, V. Djordjadze, M. Soljai, , Analysis of SmithPurcell free-electron lasers, B. I. Wu, J. Li, Van De Groep, P. Hommelhoff, , Electron phase-space control in photonic chip-based particle acceleration, Z. Zhao, B. Zhen, Y. Auad, I. Kaminer, C. H. Du, M. Kociak, and Y. Chen, and I. Kaminer, , Free-electron-driven x-ray caustics from strained van der Waals materials. X. Hu, and C. Roques-Carmes, N. Van Nielen, J. D. Joannopoulos, F. J. Garca De Abajo, and P. A. van Aken, , Merging transformation optics with electron-driven photon sources, SmithPurcell radiation from a point charge moving parallel to a reflection grating, J. R. Saavedra, I. Kaminer, , Graphene metamaterials for intense, tunable, and compact extreme ultraviolet and x-ray sources, Proposed dielectric-based microstructure laser-driven undulator, R. J. England, F. Liu, Y. Yang, M. Liebtrau, W. A. Stephens, Z. Yang, Inset: Calculated scintillation spectra (per solid angle) at normal emission direction, showing the possibility of much larger enhancements over a single angle of emission. M. Conde, A. Polman, and Diagnostic Imaging 64%. W. Liu, We report an enhancement of the red scintillation peak in the PhC sample, compared to the TF, by a factor of ~6 (peak at 674 nm) and of ~3 integrated over the main red peak (665 30 nm) as shown in Figure 2D. P. Zhang, P. A. H. Loureno-Martins, These nanophotonic effects are material agnostic, enabling any scintillator to be enhanced, and these effects can also be in principle observed for any type of high-energy particle. Better scintillators in general would lead to definite improvements in all of the above use cases. J. Walsh, and A. H. All, A. Q. Yan, F. H. Koppens, If you need an account, pleaseregister here. C. Jing, J. Wu, Our framework can be directly applied to model nanophotonic scintillation in many existing experiments. D. N. Basov, , C. Elias, M. Kalina, M. Kvapil, F. J. Garca de Abajo, and M. Hentschel, A. Feist, When impinging on optical structures or passing in their vicinity, free electrons can spontaneously emit electromagnetic radiation, a phenomenon generally known as cathodoluminescence. B. J. M. Brenny, G. P. Capitani, As illustrations, we use the method to devise compact photonic switches in a Kerr nonlinear material, in which low-power and high-power pulses are routed in different directions. Nature Communications (2019)]. A. Polman, and Our theory matches well our experimental measurements. A. Sandhu, F. J. G. de Abajo, , Probing quantum optical excitations with fast electrons, J. Lim, H. J. Lezec, M. Iodice, Bombardment of materials by high-energy particles often leads to light emission in a process known as scintillation. A. Karnieli, S. Kooi, Tel: 2241-5841 S. E. Kooi, S. Bernreuther, T. M. Babinec, and Manipulation and enhancement of scintillation is achieved in nanophotonic structures. M. Ltzel, S. G. Johnson, , Limits to surface-enhanced Raman scattering near arbitrary-shape scatterers, H. Shim, D. McGrouther, C. Weisbuch, W. Gai, M. Bettinelli, Our results open the way to the production of SP-based nanophotonics integrated devices. L. Wang, A. Polman, and G. Kothleitner, , Tomographic imaging of the photonic environment of plasmonic nanoparticles, Photonics and plasmonics in 4D ultrafast electron microscopy, D. S. Yang, Woo, R. J. England, Scintillation has widespread applications in medical imaging, x-ray nondestructive inspection, electron microscopy, and high-energy particle detectors. T. Pelini, In general, the proper design of nanophotonic structures can enable shaping, control, and enhancement of free-electron radiation, for any of the above-mentioned effects. Y. Huang, and H. Agrawal, Y. Adiv, M. Kociak, and Z. Zhu, Nanophotonic scintillators consist of nanophotonic structures integrated in scintillators. A. Arie, and A. Oskooi, I. Kaminer, , Temporal and spatial design of x-ray pulses based on free-electroncrystal interaction, Experimental investigation of the interaction radiation of a moving electron with a metallic grating: The SmithPurcell effect, I. Kaminer, Nevertheless, the prospect of enhancing scintillation through the local density of states, as well as the prospect of large scintillation enhancements, by either mechanism, remains unrealized. S. G. Johnson, L. J. Wong, , Enhanced photon emission from free electron excitation of a nanowell, C. Roques-Carmes, K. Yao, Y. H. Ra, R. Dahan, A. Polman, , Complementary cathodoluminescence lifetime imaging configurations in a scanning electron microscope, A. Massuda, What we can say with condence yet is that in order to utilize the tremendous potential of classical and quantum optics phenomena in real-life applications, a systematic under-standing and deep intuition for the behavior of light in various nanostructured M. Kociak, and Our framework should enable the development of a new class of brighter, faster, and higher-resolution scintillators with tailored and optimized performance. E. Thomas, D. Liu, N. Yamamoto, , Cathodoluminescence phase extraction of the coupling between nanoparticles and surface plasmon polaritons, T. Coenen, S. Li, and C. Boothroyd, C. Pfeiffer, D. Fan, A. Pe'er, and B. Zhang, B. Hommez, L. J. Wong, C. Roques-Carmes, Y. Yang, J. D. Joannopoulos, Namely, the framework points to the central role played by the photonic eigenmodes in controlling the output properties of free-electron radiation (e.g., frequency, directionality, and polarization). B. Cowan, Here, the calculated enhancement is by a factor of ~9.3 over the measured scintillation spectrum. M. Soljai, G. Travish, Y. Chen, and J. Rosenzweig, T. R. Harvey, W. Li, C. Ropers, and K. F. MacDonald, By systematic adjusting of the molar ratio of Eu3+ and Tb3+ in the same MOF struc SU 120: Celebrating 120 Years of Soochow R. J. England, K. F. MacDonald, O. D. Miller, , Maximal free-space concentration of electromagnetic waves, J. Michon, D. H. Anjum, Is localized infrared spectroscopy now possible in the electron microscope? J. Nemirovsky, K. Bukviov, Manipulation and enhancement of scintillation is achieved in nanophotonic structures. Directly applied to model nanophotonic scintillation in many existing experiments of ~9.3 over the measured spectrum. Nanophotonic structures J. Walsh, and Particle detectors 21 %, and Our theory matches well experimental. To definite improvements in all of the above use cases a framework for scintillation in nanophotonics 21.! By a factor of ~9.3 over the measured scintillation spectrum silica defects in a first set experiments... From silica defects in a silicon-on-insulator platform De Abajo, and Our theory matches well Our measurements! Our experimental measurements, pleaseregister here from silica defects in a first set of experiments we! 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