Relevant bibliographies by topics / Nanophotonic circuits

Academic literature on the topic 'Nanophotonic circuits'

Author: Grafiati
Published: 10 December 2022
Last updated: 29 January 2023

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Journal articles on the topic "Nanophotonic circuits"

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Rath, Patrik, Michael Hirtz, Georgia Lewes-Malandrakis, Dietmar Brink, Christoph Nebel, and Wolfram H. P. Pernice. "Nanophotonic Circuits: Diamond Nanophotonic Circuits Functionalized by Dip-pen Nanolithography (Advanced Optical Materials 3/2015)." Advanced Optical Materials 3, no. 3 (March 2015): 273. http://dx.doi.org/10.1002/adom.201570014.

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Chen, Jianjun, and Kexiu Rong. "Nanophotonic devices and circuits based on colloidal quantum dots." Materials Chemistry Frontiers 5, no. 12 (2021): 4502–37. http://dx.doi.org/10.1039/d0qm01118e.

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Colloidal quantum dots provide a powerful platform to achieve numerous classes of solution-processed photonic devices. This review summarizes the recent progress in CQD-based passive and active nanophotonic devices as well as nanophotonic circuits.
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Demertzis, Konstantinos, Georgios D. Papadopoulos, Lazaros Iliadis, and Lykourgos Magafas. "A Comprehensive Survey on Nanophotonic Neural Networks: Architectures, Training Methods, Optimization, and Activations Functions." Sensors 22, no. 3 (January 18, 2022): 720. http://dx.doi.org/10.3390/s22030720.

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In the last years, materializations of neuromorphic circuits based on nanophotonic arrangements have been proposed, which contain complete optical circuits, laser, photodetectors, photonic crystals, optical fibers, flat waveguides and other passive optical elements of nanostructured materials, which eliminate the time of simultaneous processing of big groups of data, taking advantage of the quantum perspective, and thus highly increasing the potentials of contemporary intelligent computational systems. This article is an effort to record and study the research that has been conducted concerning the methods of development and materialization of neuromorphic circuits of neural networks of nanophotonic arrangements. In particular, an investigative study of the methods of developing nanophotonic neuromorphic processors, their originality in neuronic architectural structure, their training methods and their optimization was realized along with the study of special issues such as optical activation functions and cost functions. The main contribution of this research work is that it is the first time in the literature that the most well-known architectures, training methods, optimization and activations functions of the nanophotonic networks are presented in a single paper. This study also includes an extensive detailed meta-review analysis of the advantages and disadvantages of nanophotonic networks.
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Shen, Yichen, Nicholas C. Harris, Scott Skirlo, Mihika Prabhu, Tom Baehr-Jones, Michael Hochberg, Xin Sun, et al. "Deep learning with coherent nanophotonic circuits." Nature Photonics 11, no. 7 (June 12, 2017): 441–46. http://dx.doi.org/10.1038/nphoton.2017.93.

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Xiong, Chi, Wolfram Pernice, Carsten Schuck, and Hong X. Tang. "Integrated Photonic Circuits in Gallium Nitride and Aluminum Nitride." International Journal of High Speed Electronics and Systems 23, no. 01n02 (March 2014): 1450001. http://dx.doi.org/10.1142/s0129156414500013.

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Integrated optics is a promising optical platform both for its enabling role in optical interconnects and applications in on-chip optical signal processing. In this paper, we discuss the use of group III-nitride (GaN, AlN) as a new material system for integrated photonics compatible with silicon substrates. Exploiting their inherent second-order nonlinearity we demonstrate and second, third harmonic generation in GaN nanophotonic circuits and high-speed electro-optic modulation in AlN nanophotonic circuits.
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Abdollahramezani, Sajjad, Omid Hemmatyar, Hossein Taghinejad, Alex Krasnok, Yashar Kiarashinejad, Mohammadreza Zandehshahvar, Andrea Alù, and Ali Adibi. "Tunable nanophotonics enabled by chalcogenide phase-change materials." Nanophotonics 9, no. 5 (June 6, 2020): 1189–241. http://dx.doi.org/10.1515/nanoph-2020-0039.

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AbstractNanophotonics has garnered intensive attention due to its unique capabilities in molding the flow of light in the subwavelength regime. Metasurfaces (MSs) and photonic integrated circuits (PICs) enable the realization of mass-producible, cost-effective, and efficient flat optical components for imaging, sensing, and communications. In order to enable nanophotonics with multipurpose functionalities, chalcogenide phase-change materials (PCMs) have been introduced as a promising platform for tunable and reconfigurable nanophotonic frameworks. Integration of non-volatile chalcogenide PCMs with unique properties such as drastic optical contrasts, fast switching speeds, and long-term stability grants substantial reconfiguration to the more conventional static nanophotonic platforms. In this review, we discuss state-of-the-art developments as well as emerging trends in tunable MSs and PICs using chalcogenide PCMs. We outline the unique material properties, structural transformation, and thermo-optic effects of well-established classes of chalcogenide PCMs. The emerging deep learning-based approaches for the optimization of reconfigurable MSs and the analysis of light-matter interactions are also discussed. The review is concluded by discussing existing challenges in the realization of adjustable nanophotonics and a perspective on the possible developments in this promising area.
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Rath, P., S. Ummethala, S. Diewald, G. Lewes-Malandrakis, D. Brink, N. Heidrich, C. Nebel, and W. H. P. Pernice. "Diamond electro-optomechanical resonators integrated in nanophotonic circuits." Applied Physics Letters 105, no. 25 (December 22, 2014): 251102. http://dx.doi.org/10.1063/1.4901105.

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Splitthoff, Lukas, Martin A. Wolff, Thomas Grottke, and Carsten Schuck. "Tantalum pentoxide nanophotonic circuits for integrated quantum technology." Optics Express 28, no. 8 (April 8, 2020): 11921. http://dx.doi.org/10.1364/oe.388080.

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Stegmaier, Matthias, and Wolfram H. P. Pernice. "Broadband directional coupling in aluminum nitride nanophotonic circuits." Optics Express 21, no. 6 (March 15, 2013): 7304. http://dx.doi.org/10.1364/oe.21.007304.

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Fang, Yurui, and Mengtao Sun. "Nanoplasmonic waveguides: towards applications in integrated nanophotonic circuits." Light: Science & Applications 4, no. 6 (June 2015): e294-e294. http://dx.doi.org/10.1038/lsa.2015.67.

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Dissertations / Theses on the topic "Nanophotonic circuits"

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Dixon, James Edward. "Towards integrated scalable nanophotonic circuits." Thesis, University of Sheffield, 2017. http://etheses.whiterose.ac.uk/18282/.

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This thesis presents optical measurements used to explore nanophotonic circuits composed of III-V semiconductors with embedded quantum dots. The focus of this work is to investigate issues related to the scalability and performance of these structures. A technique to register the position of a quantum dot, relative to pre-fabricated registration markers, with the aid of a solid immersion lens, is developed. The variance in the repeatedly registered position of the quantum dot is shown to be significantly reduced as a result of the solid immersion lens, compared with positions registered without a solid immersion lens. The total error of the deterministic fabrication, using position registered quantum dots, is small when compared to the size of optical fields. Confirmation of this has been achieved through two independent methods. Re-registration of the position relative to deterministically positioned registration markers show that the total error of deterministic fabrication is small. Additionally, the demonstration of optical spin readout, via the deterministic positioning of a quantum dot at a chiral point of a suspended nanobeam waveguide, further confirms the positional accuracy of the technique. The demonstration of efficiently coupled single photons form an embedded quantum into a nanobeam waveguide, with enhanced coherence lengths due to resonant excitation, is achieved. A high level of resonant laser rejection is demonstrated due to the orthogonal excitation and waveguide propagation directions.
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Coles, Rikki J. "Quantum optical circuits using III-V nanophotonic structures." Thesis, University of Sheffield, 2015. http://etheses.whiterose.ac.uk/9624/.

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Lin, Chunchen. "Semiconductor-based nanophotonic and terahertz devices for integrated circuits applications." Access to citation, abstract and download form provided by ProQuest Information and Learning Company; downloadable PDF file 7.48 Mb., 180 p, 2006. http://wwwlib.umi.com/dissertations/fullcit/3221130.

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Ovvyan, Anna [Verfasser], and U. [Akademischer Betreuer] Lemmer. "Nanophotonic circuits for single photon emitters / Anna Ovvyan ; Betreuer: U. Lemmer." Karlsruhe : KIT-Bibliothek, 2019. http://d-nb.info/1184990077/34.

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Saad-Bin-Alam, Md. "Analysis of Plasmonic Metastructures for Engineered Nonlinear Nanophotonics." Thesis, Université d'Ottawa / University of Ottawa, 2019. http://hdl.handle.net/10393/39120.

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This Master’s dissertation focuses on engineering artificial nanostructures, namely, arrays of metamolecules on a substrate (metasurfaces), with the goal to achieve the desired linear and nonlinear optical responses. Specifically, a simple analytical model capable of predicting optical nonlinearity of an individual metamolecule has been developed. The model allows one to estimate the nonlinear optical response (linear polarizability and nonlinear hyperpolarizabilities) of a metamolecule based on the knowledge of its shape, dimensions, and material. In addition, a new experimental approach to measure hyperpolarizability has also been investigated. As another research effort, a 2D plasmonic metasurface with the collective behaviour of the metamolecules known as hybrid plasmonic-Fabry-Perot cavity and surface lattice resonances was designed, fabricated and optically characterized. We experimentally discovered a novel way of coupling the microcavity resonances and the diffraction orders of the plasmonic metamolecule arrays with the low-quality plasmon resonance to generate multiple sharp resonances with the higher quality factors. Finally, we experimentally observed and demonstrated a record ultra-high-Q surface lattice resonance from a plasmonic metasurface. These novel results can be used to render highly efficient nonlinear optical responses relying on high optical field localization, and can serve as the stepping stone towards achieving practical artificial nanophotonic devices with tailored linear and nonlinear optical responses.
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Wang, Zhechao. "Investigation of New Concepts and Solutions for Silicon Nanophotonics." Doctoral thesis, KTH, Mikroelektronik och tillämpad fysik, MAP, 2010. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-13029.

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Nowadays, silicon photonics is a widely studied research topic. Its high-index-contrast and compatibility with the complementary metal-oxide-semiconductor technology make it a promising platform for low cost high density integration. Several general problems have been brought up, including the lack of silicon active devices, the difficulty of light coupling, the polarization dependence, etc. This thesis aims to give new attempts to novel solutions for some of these problems. Both theoretical modeling and experimental work have been done. Several numerical methods are reviewed first. The semi-vectorial finite-difference mode solver in cylindrical coordinate system is developed and it is mainly used for calculating the eigenmodes of the waveguide structures employed in this thesis. The finite-difference time-domain method and beam propagation method are also used to analyze the light propagation in complex structures. The fabrication and characterization technologies are studied. The fabrication is mainly based on clean room facilities, including plasma assisted film deposition, electron beam lithography and dry etching. The vertical coupling system is mainly used for characterization in this thesis. Compared with conventional butt-coupling system, it can provide much higher coupling efficiency and larger alignment tolerance. Two novel couplers related to silicon photonic wires are studied. In order to improve the coupling efficiency of a grating coupler, a nonuniform grating is theoretically designed to maximize the overlap between the radiated light profile and the optical fiber mode. Over 60% coupling efficiency is obtained experimentally. Another coupler facilitating the light coupling between silicon photonic wires and slot waveguides is demonstrated, both theoretically and experimentally. Almost lossless coupling is achieved in experiments. Two approaches are studied to realize polarization insensitive devices based on silicon photonic wires. The first one is the use of a sandwich waveguide structure to eliminate the polarization dependent wavelength of a microring resonator. By optimizing the multilayer structure, we successfully eliminate the large birefringence in an ultrasmall ring resonator. Another approach is to use polarization diversity scheme. Two key components of the scheme are studied. An efficient polarization beam splitter based on a one-dimensional grating coupler is theoretically designed and experimentally demonstrated. This polarization beam splitter can also serve as an efficient light coupler between silicon-on-insulator waveguides and optical fibers. Over 50% coupling efficiency for both polarizations and -20dB extinction ratio between them are experimentally obtained. A compact polarization rotator based on silicon photonic wire is theoretically analyzed. 100% polarization conversion is achievable and the fabrication tolerance is relatively large by using a compensation method. A novel integration platform based on nano-epitaxial lateral overgrowth technology is investigated to realize monolithic integration of III-V materials on silicon. A silica mask is used to block the threading dislocations from the InP seed layer on silicon. Technologies such as hydride vapor phase epitaxy and chemical-mechanical polishing are developed. A thin dislocation free InP layer on silicon is obtained experimentally.
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Burgos, Stanley P. "Coupled Plasmonic Systems and Devices: Applications in Visible Metamaterials, Nanophotonic Circuits, and CMOS Imaging." Thesis, 2013. https://thesis.library.caltech.edu/7835/1/stanley_burgos_2013_thesis_original.pdf.

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With the size of transistors approaching the sub-nanometer scale and Si-based photonics pinned at the micrometer scale due to the diffraction limit of light, we are unable to easily integrate the high transfer speeds of this comparably bulky technology with the increasingly smaller architecture of state-of-the-art processors. However, we find that we can bridge the gap between these two technologies by directly coupling electrons to photons through the use of dispersive metals in optics. Doing so allows us to access the surface electromagnetic wave excitations that arise at a metal/dielectric interface, a feature which both confines and enhances light in subwavelength dimensions - two promising characteristics for the development of integrated chip technology. This platform is known as plasmonics, and it allows us to design a broad range of complex metal/dielectric systems, all having different nanophotonic responses, but all originating from our ability to engineer the system surface plasmon resonances and interactions. In this thesis, we demonstrate how plasmonics can be used to develop coupled metal-dielectric systems to function as tunable plasmonic hole array color filters for CMOS image sensing, visible metamaterials composed of coupled negative-index plasmonic coaxial waveguides, and programmable plasmonic waveguide network systems to serve as color routers and logic devices at telecommunication wavelengths.
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Books on the topic "Nanophotonic circuits"

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Ibrahim, Abdulhalim, and ScienceDirect (Online service), eds. Integrated nanophotonic devices. Norwich, N.Y: William Andrew, 2010.

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Lee, El-Hang. VLSI micro- and nanophotonics : science, technology, and applications. Boca Raton, FL: CRC Press, 2010.

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Weiner, John. Light-matter interaction: Physics and engineering at the nanoscale. Oxford: Oxford University Press, 2013.

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Ping-Tong, Ho, ed. Light-matter interaction. Hoboken, N.J: Wiley, 2003.

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Zalevsky, Zeev, and Ibrahim Abdulhalim. Integrated Nanophotonic Devices. William Andrew, 2014.

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Zalevsky, Zeev, and Ibrahim Abdulhalim. Integrated Nanophotonic Devices. Elsevier - Health Sciences Division, 2017.

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Zalevsky, Zeev, and Ibrahim Abdulhalim. Integrated Nanophotonic Devices. Elsevier Science & Technology Books, 2010.

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Zalevsky, Zeev, and Ibrahim Abdulhalim. Integrated Nanophotonic Devices. Elsevier Science & Technology Books, 2014.

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Nanophotonics: Devices, Circuits, and Systems. Pan Stanford Publishers, 2012.

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Yupapin, Preecha. Nanophotonics: Devices, Circuits, and Systems. Jenny Stanford Publishing, 2013.

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Book chapters on the topic "Nanophotonic circuits"

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Hartmann, W., P. Rath, and W. H. P. Pernice. "Diamond Nanophotonic Circuits." In NATO Science for Peace and Security Series B: Physics and Biophysics, 371. Dordrecht: Springer Netherlands, 2018. http://dx.doi.org/10.1007/978-94-024-1544-5_22.

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Lin, Lih Y. "Quantum Dot Nanophotonic Integrated Circuits." In Encyclopedia of Nanotechnology, 3389–99. Dordrecht: Springer Netherlands, 2016. http://dx.doi.org/10.1007/978-94-017-9780-1_193.

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Lin, Lih Y., Wafa’ T. Al-Jamal, and Kostas Kostarelos. "Quantum Dot Nanophotonic Integrated Circuits." In Encyclopedia of Nanotechnology, 2187–96. Dordrecht: Springer Netherlands, 2012. http://dx.doi.org/10.1007/978-90-481-9751-4_193.

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Feldmann, Johannes, and Wolfram Pernice. "Hybrid Phase-Change Nanophotonic Circuits." In 21st Century Nanoscience – A Handbook, 4–1. Boca Raton, Florida : CRC Press, [2020]: CRC Press, 2020. http://dx.doi.org/10.1201/9780429351617-4.

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Pernice, Wolfram. "Nanophotonic Circuits forUnconventional Computing Applications." In NATO Science for Peace and Security Series B: Physics and Biophysics, 125–32. Dordrecht: Springer Netherlands, 2022. http://dx.doi.org/10.1007/978-94-024-2138-5_7.

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Dwyer, Chris, Arjun Rallapalli, Mohammad Mottaghi, and Siyang Wang. "DNA Self-Assembled Nanostructures for Resonance Energy Transfer Circuits." In Nanophotonic Information Physics, 41–65. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-40224-1_2.

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Kasai, Seiya, Hong-Quan Zhao, Yuta Shiratori, Tamer Mohamed, and Svetlana N. Yanushkevich. "Boolean Logic Circuits on Nanowire Networks and Related Technologies." In Nanophotonic Information Physics, 115–43. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-40224-1_5.

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Roelkens, Günther, and Dries Van Thourhout. "Interfacing Silicon Nanophotonic Integrated Circuits and Single-Mode Optical Fibers with Diffraction Gratings." In Topics in Applied Physics, 71–94. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-10506-7_3.

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Takazawa, K., J. Inoue, and K. Mitsuishi. "Miniaturized Photonic Circuit Components Constructed from Organic Dye Nanofiber Waveguides." In Nano-Optics and Nanophotonics, 119–39. Berlin, Heidelberg: Springer Berlin Heidelberg, 2014. http://dx.doi.org/10.1007/978-3-662-45082-6_5.

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Khan, Sumaya, and Ishu Sharma. "Revolutionary Future Using the Ultimate Potential of Nanophotonics." In Photonic Materials: Recent Advances and Emerging Applications, 141–59. BENTHAM SCIENCE PUBLISHERS, 2023. http://dx.doi.org/10.2174/9789815049756123010011.

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As the world is modernizing, it is noteworthy to mention photonics and its categorization based on size. Despite the components of light being invisible to the human eye, nature never ceases to amaze us with its idiosyncratic phenomenon. Furthermore, the manipulation of the matter is confined to the nanoscale as a part of the progression. Adding nanotechnology to photonics emerges out as nanophotonics which is the cutting-edge tech of the twenty-first century. Human beings have acclimated to the concept of photonics, furthermore, nanophotonics is the science of miniaturization study, potentially helping the technology to modify itself into the sophistication of the equipment and thereby be of assistance in various disciplines of science and technology. One can illustrate nanophotonics by considering the fabrication processes of nanomaterials. In variegated applications, these nanoscale processes will refine and produce structures with high precision and accuracy. Meanwhile, groundbreaking inventions and discoveries have been going around, from communications to data processing, from detecting diseases to treating diseases at the outset. As one stresses on the idea of nanophotonics, it never reaches a dead-end, however, this explains how vast the universe and each of the components co-existing are infinitesimally beyond humans' reach. Nevertheless, nanophotonics and its applications bring about remarkable multidisciplinary challenges which require proficient and well-cultivated researchers. Despite the fact it has several advantages, it carries its downside, which requires a detailed analysis of any matter. Using state-of-the-art technology, one can constrict light into a nanometer scale using different principle methodologies such as surface plasmons, metal optics, near field optics, and metamaterials. The distinctive optical properties of nanophotonics call out specific applications in the electronics field such as interaction chips, tiny devices, transistor filaments, etc. When compared to conventional electronic integrated circuits, the pace at which data using nanophotonic devices is sent is exceptionally fast, accurate, and has a better signal processing capability. As a result of the integration of nanotechnology with photonic circuit technology, high-speed data processing with an average processing speed on the order of terabits per second is possible. Furthermore, nano-integrated photonics technology is capable of comprehensive data storage and processing, which inevitably lays the groundwork for the fabrication, quantification, control, and functional requirements of novel optical science and technology. The majority of applications include nanolithography, near-field scanning optical microscopy, nanotube nanomotors, and others. This explains about the working principle, different materials utilized, and several other applications for a better understanding.
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Conference papers on the topic "Nanophotonic circuits"

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Nezhad, Maziar P., Aleksandar Simic, Olesya Bondarenko, Boris A. Slutsky, Amit Mizrahi, and Yeshaiahu Fainman. "Nanophotonic devices and circuits." In SPIE OPTO, edited by Louay A. Eldada and El-Hang Lee. SPIE, 2011. http://dx.doi.org/10.1117/12.877118.

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Gruhler, Nico, Maik Stappers, and Wolfram Pernice. "Chipscale diamond nanophotonic circuits." In Diamond Photonics - Physics, Technologies and Applications. Washington, D.C.: OSA, 2019. http://dx.doi.org/10.1364/dp.2019.46.

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Yatsui, Takashi, Makoto Naruse, and Motoichi Ohtsu. "Plasmonic circuits for nanophotonic devices." In SPIE Optics + Photonics, edited by Mark I. Stockman. SPIE, 2006. http://dx.doi.org/10.1117/12.680108.

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Bogaerts, Wim, Pieter Dumon, Shankar Kumar Selvaraja, Dries Van Thourhout, and Roel Baets. "Silicon nanophotonic waveguide circuits and devices." In LEOS 2008 - 21st Annual Meeting of the IEEE Lasers and Electro-Optics Society (LEOS 2008). IEEE, 2008. http://dx.doi.org/10.1109/leos.2008.4688611.

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Vlasov, Yu A., E. Dulkeith, F. Xia, L. Sekaric, S. Assefa, M. O’Boyle, and S. J. McNab. "Passive and Active Silicon Nanophotonic Circuits." In Frontiers in Optics. Washington, D.C.: OSA, 2005. http://dx.doi.org/10.1364/fio.2005.ftuo3.

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Shen, Yichen, Nicholas C. Harris, Dirk Englund, and Marin SoljaCiC. "Deep learning with coherent nanophotonic circuits." In 2017 Fifth Berkeley Symposium on Energy Efficient Electronic Systems & Steep Transistors Workshop (E3S). IEEE, 2017. http://dx.doi.org/10.1109/e3s.2017.8246190.

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Shen, Yichen, Nicholas C. Harris, Scott Skirlo, Dirk Englund, and Marin Soljacic. "Deep learning with coherent nanophotonic circuits." In 2017 IEEE Photonics Society Summer Topical Meeting Series (SUM). IEEE, 2017. http://dx.doi.org/10.1109/phosst.2017.8012714.

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Swillam, Mohamed A. "Smart Techniques for Modelling Nanophotonic Circuits." In 14th International Conference on Numerical Simulation of Optoelectronic Devices (NUSOD 2014). IEEE, 2014. http://dx.doi.org/10.1109/nusod.2014.6935376.

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Yatsui, Takashi, Gyu-Chul Yi, and Motoichi Ohtsu. "Progress in developing nanophotonic integrated circuits." In SPIE Proceedings, edited by Mircea Udrea. SPIE, 2008. http://dx.doi.org/10.1117/12.801925.

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Mabuchi, Hideo. "Coherent-feedback control in nanophotonic circuits." In SPIE Defense, Security, and Sensing, edited by Thomas George, M. Saif Islam, and Achyut Dutta. SPIE, 2012. http://dx.doi.org/10.1117/12.920009.

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Reports on the topic "Nanophotonic circuits"

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Gunn, Cary. Nanophotonic Integrated Circuits. Fort Belvoir, VA: Defense Technical Information Center, May 2003. http://dx.doi.org/10.21236/ada423912.

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