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Добірка наукової літератури з теми "Integrated nanophotonic circuit"

Автор: Grafiati
Опубліковано: 10 березня 2023

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Статті в журналах з теми "Integrated nanophotonic circuit"

1

Goltsman, Gregory. "Quantum photonic integrated circuits with waveguide integrated superconducting nanowire single-photon detectors." EPJ Web of Conferences 190 (2018): 02004. http://dx.doi.org/10.1051/epjconf/201819002004.

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We show the design, a history of development as well as the most successful and promising approaches for QPICs realization based on hybrid nanophotonic-superconducting devices, where one of the key elements of such a circuit is a waveguide integrated superconducting single-photon detector (WSSPD). The potential of integration with fluorescent molecules is discussed also.
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2

Pyatkov, Felix, Svetlana Khasminskaya, Vadim Kovalyuk, Frank Hennrich, Manfred M. Kappes, Gregory N. Goltsman, Wolfram H. P. Pernice, and Ralph Krupke. "Sub-nanosecond light-pulse generation with waveguide-coupled carbon nanotube transducers." Beilstein Journal of Nanotechnology 8 (January 5, 2017): 38–44. http://dx.doi.org/10.3762/bjnano.8.5.

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Carbon nanotubes (CNTs) have recently been integrated into optical waveguides and operated as electrically-driven light emitters under constant electrical bias. Such devices are of interest for the conversion of fast electrical signals into optical ones within a nanophotonic circuit. Here, we demonstrate that waveguide-integrated single-walled CNTs are promising high-speed transducers for light-pulse generation in the gigahertz range. Using a scalable fabrication approach we realize hybrid CNT-based nanophotonic devices, which generate optical pulse trains in the range from 200 kHz to 2 GHz with decay times below 80 ps. Our results illustrate the potential of CNTs for hybrid optoelectronic systems and nanoscale on-chip light sources.
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3

Shiue, Ren-Jye, Dmitri K. Efetov, Gabriele Grosso, Cheng Peng, Kin Chung Fong, and Dirk Englund. "Active 2D materials for on-chip nanophotonics and quantum optics." Nanophotonics 6, no. 6 (March 15, 2017): 1329–42. http://dx.doi.org/10.1515/nanoph-2016-0172.

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AbstractTwo-dimensional materials have emerged as promising candidates to augment existing optical networks for metrology, sensing, and telecommunication, both in the classical and quantum mechanical regimes. Here, we review the development of several on-chip photonic components ranging from electro-optic modulators, photodetectors, bolometers, and light sources that are essential building blocks for a fully integrated nanophotonic and quantum photonic circuit.
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4

Matsuda, Nobuyuki, and Hiroki Takesue. "Generation and manipulation of entangled photons on silicon chips." Nanophotonics 5, no. 3 (August 1, 2016): 440–55. http://dx.doi.org/10.1515/nanoph-2015-0148.

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AbstractIntegrated quantum photonics is now seen as one of the promising approaches to realize scalable quantum information systems. With optical waveguides based on silicon photonics technologies, we can realize quantum optical circuits with a higher degree of integration than with silica waveguides. In addition, thanks to the large nonlinearity observed in silicon nanophotonic waveguides, we can implement active components such as entangled photon sources on a chip. In this paper, we report recent progress in integrated quantum photonic circuits based on silicon photonics. We review our work on correlated and entangled photon-pair sources on silicon chips, using nanoscale silicon waveguides and silicon photonic crystal waveguides. We also describe an on-chip quantum buffer realized using the slow-light effect in a silicon photonic crystal waveguide. As an approach to combine the merits of different waveguide platforms, a hybrid quantum circuit that integrates a silicon-based photon-pair source and a silica-based arrayed waveguide grating is also presented.
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5

Tassaert, M., S. Keyvaninia, D. Van Thourhout, W. M. J. Green, Y. Vlasov, and G. Roelkens. "An optically pumped nanophotonic InP/InGaAlAs optical amplifier integrated on a SOI waveguide circuit." Optical and Quantum Electronics 44, no. 12-13 (March 9, 2012): 513–19. http://dx.doi.org/10.1007/s11082-012-9568-x.

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6

Uppu, Ravitej, Freja T. Pedersen, Ying Wang, Cecilie T. Olesen, Camille Papon, Xiaoyan Zhou, Leonardo Midolo, et al. "Scalable integrated single-photon source." Science Advances 6, no. 50 (December 2020): eabc8268. http://dx.doi.org/10.1126/sciadv.abc8268.

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Анотація:
Photonic qubits are key enablers for quantum information processing deployable across a distributed quantum network. An on-demand and truly scalable source of indistinguishable single photons is the essential component enabling high-fidelity photonic quantum operations. A main challenge is to overcome noise and decoherence processes to reach the steep benchmarks on generation efficiency and photon indistinguishability required for scaling up the source. We report on the realization of a deterministic single-photon source featuring near-unity indistinguishability using a quantum dot in an “on-chip” planar nanophotonic waveguide circuit. The device produces long strings of >100 single photons without any observable decrease in the mutual indistinguishability between photons. A total generation rate of 122 million photons per second is achieved, corresponding to an on-chip source efficiency of 84%. These specifications of the single-photon source are benchmarked for boson sampling and found to enable scaling into the regime of quantum advantage.
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7

Van Campenhout, J., P. Rojo Romeo, P. Regreny, C. Seassal, D. Van Thourhout, S. Verstuyft, L. Di Cioccio, J. M. Fedeli, C. Lagahe, and R. Baets. "Electrically pumped InP-based microdisk lasers integrated with a nanophotonic silicon-on-insulator waveguide circuit." Optics Express 15, no. 11 (2007): 6744. http://dx.doi.org/10.1364/oe.15.006744.

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8

Hadden, J. P., Cobi Maynard, Daryl M. Beggs, Robert A. Taylor, and Anthony J. Bennett. "Design of free-space couplers for suspended triangular nano-beam waveguides." Journal of Physics D: Applied Physics 55, no. 47 (October 5, 2022): 474002. http://dx.doi.org/10.1088/1361-6463/ac941e.

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Abstract Photonic waveguides (WGs) with triangular cross section are being investigated for material systems such as diamond, glasses and gallium nitride, which lack easy options to create conventional rectangular nanophotonic waveguides. The design rules for optical elements in these triangular WGs, such as couplers and gratings, are not well established. Here we present simulations of elements designed to couple light into, and out of, triangular WGs from the vertical direction, which can be implemented with current angled-etch fabrication technology. The devices demonstrate coupling efficiencies approaching 50% for light focused from a high numerical aperture objective. The implementation of such couplers will enable fast and efficient testing of closely spaced integrated circuit components.
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9

Chew, Xiong Yeu, Guang Ya Zhou, and Fook Siong Chau. "Novel Doubly Nano-Scale Perturbative Resonance Control of a Free-Suspending Photonic Crystal Structure." Applied Mechanics and Materials 83 (July 2011): 147–50. http://dx.doi.org/10.4028/www.scientific.net/amm.83.147.

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Анотація:
The impact of developing nanophotonic components have proven to be a promising research on the future optical integrated circuit complementing the current scaling of semiconductors for faster board-board, chip-chip interconnect speeds. Essentially photonic crystals (PhC) symbolize an emerging class of periodic nanomaterials that offers flexibilities in achieving novel devices. Based on the investigations of the high-Q resonance mode energy distributions, we optimized the nano­scale tip for optimal perturbative effect with low loss resonance control in the optical near field regime. In this study to achieve larger spectral resonance, we proposed using a novel doubly nano­scale perturbative tip to achieve optimal accurate photonic crystal resonance control. Such method may be driven by a nano-electromechanical (NEMS) system that may be fabricated with monolithic approaches.
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Romeira, Bruno, José M. L. Figueiredo та Julien Javaloyes. "NanoLEDs for energy-efficient and gigahertz-speed spike-based sub-λ neuromorphic nanophotonic computing". Nanophotonics 9, № 13 (25 червня 2020): 4149–62. http://dx.doi.org/10.1515/nanoph-2020-0177.

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AbstractEvent-activated biological-inspired subwavelength (sub-λ) photonic neural networks are of key importance for future energy-efficient and high-bandwidth artificial intelligence systems. However, a miniaturized light-emitting nanosource for spike-based operation of interest for neuromorphic optical computing is still lacking. In this work, we propose and theoretically analyze a novel nanoscale nanophotonic neuron circuit. It is formed by a quantum resonant tunneling (QRT) nanostructure monolithic integrated into a sub-λ metal-cavity nanolight-emitting diode (nanoLED). The resulting optical nanosource displays a negative differential conductance which controls the all-or-nothing optical spiking response of the nanoLED. Here we demonstrate efficient activation of the spiking response via high-speed nonlinear electrical modulation of the nanoLED. A model that combines the dynamical equations of the circuit which considers the nonlinear voltage-controlled current characteristic, and rate equations that takes into account the Purcell enhancement of the spontaneous emission, is used to provide a theoretical framework to investigate the optical spiking dynamic properties of the neuromorphic nanoLED. We show inhibitory- and excitatory-like optical spikes at multi-gigahertz speeds can be achieved upon receiving exceptionally low (sub-10 mV) synaptic-like electrical activation signals, lower than biological voltages of 100 mV, and with remarkably low energy consumption, in the range of 10–100 fJ per emitted spike. Importantly, the energy per spike is roughly constant and almost independent of the incoming modulating frequency signal, which is markedly different from conventional current modulation schemes. This method of spike generation in neuromorphic nanoLED devices paves the way for sub-λ incoherent neural elements for fast and efficient asynchronous neural computation in photonic spiking neural networks.
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Дисертації з теми "Integrated nanophotonic circuit"

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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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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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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.
QC20100705
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4

Ovvyan, Anna. "Nanophotonic circuits for single photon emitters." Doctoral thesis, 2018. http://hdl.handle.net/2158/1175896.

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Nanophotonic circuits for single photon emitters. The work demonstrated in this thesis is dedicated to the engineering, simulation, fabrica-tion and investigation of the essential element base to develop hybrid fully integrated nanopho-tonic circuit with coupled single photon emitter on chip. Combining several individually opti-mized stages of photonic devices, interconnected by nanoscale waveguides on chip with eva-nescently coupled single photon emitter, is a key step to the realization of such a scheme. The main requirements which should be satisfied for building such a hybrid system on-chip, and are thus the subject of this Thesis, are, namely: integration of single photon photostable source with high Quantum Yield (QY) on chip, efficient coupling of the emitted light to nanophotonic cir-cuits, and efficient filtering of the excitation light. Silicon nitride-on-insulator was used in all the projects described in this Thesis as the platform for the realization of photonic circuits. It provides low-loss broadband optical transparency covering the entire visible range up to the near infrared spectrum. Furthermore, sufficiently high refractive index contrast of Si3N4 on SiO2 enables tight confinement of the mode in the waveguide structure and the realization of photonic circuits with small footprint. A drastic increase of the coupling efficiency of the emitted light into the waveguide mode can be achieved by placing single-photon emitter on photonic crystal cavity because of its high Quality factor and small mode volume enabling a high Purcell enhancement. To this end, a novel cross-bar 1D freestanding photonic crystal (PhC) cavity was developed for evanescent integration of single photon emitter, in particular Nanodiamonds (NDs), onto the region of the cavity. The novelty of this photonic structure is that collection of emitted light is provided via waveguide, which consists of PhC, whereas direct optical excitation is obtained through a crossed waveguide in the orthogonal direction of the in-plane cavity. Optimization of the PhC cavity architecture was performed via rounds of simulations and ver-ified by experimental measurements of fabricated devices on chip, which were found in excel-lent agreement. The next round of simulations was performed to define an optimal position of the source in the cavity region to achieve maximum Purcell enhancement, which was realized via Local Density of States (LDOS) computation. Thus, placing a single photon emitter into a determined position on the cavity region of the developed cross-bar 1D freestanding PhC enables an increase in the transmission coupling efficiency into cavity up to =71% in comparison with computed 41% in the case of coupling into waveguide mode of cross-bar structure without PhC. To block the pump light and at the same time transmit the fluorescent emitted light, compact and low-loss cascaded Mach–Zehnder interferometers (MZIs) tunable filters in the visible region embedded within nanophotonic circuit, were realized. Tunability was provided via thermo-optic effect. The design of this device, namely geometry and shape of the microheater, was optimized via thermo-optic measurements, to achieve low electrical power consumption (switching power of 12.2 mW for the case of a spiral-shape microheater), high filtration depth and low optical insertion loss. The novel design with double microheaters on top of both arms of single and cascaded MZIs allows doubling the range of the shifting amplitude of the interference fringes. The demonstrated architecture of tunable filter is multifunctional, namely allowing transmission and filtering of the desired wavelengths in a wide wavelength range. In particular, filtration depth beyond 36.5 dB of light with 532 nm wavelength and simultaneous transmission of light with 738 nm wavelength, which correspond respectively to excitation and emission wavelength of the silicon-vacancy color center in diamond, was demonstrated. The results were published in Ovvyan, A. P.; Gruhler, N.; Ferrari, S.; Pernice, W. H. P. Cascaded Mach-Zehnder interferometer tunable filters. Journal of Optics 2016, 18, 064011 https://doi.org/10.1088/2040-8978/18/6/064011 Another filter with non-repetitive stopband with bandwidth of several nanometers was developed in this thesis. A non-uniform Bragg grating filter with novel double Gaussian apodization was proposed, whose fabrication required a single lithography step. This optimized Bragg filter provides a 21 dB filtration depth with a 3-dB bandwidth of 5.6 nm, insuring negligible insertion loss in the best case, while averaged insertion loss in reflected signal is 4.1dB (including loss in splitter). One of the first Hybrid organic molecule Dibenzoterrylene (DBT) coupled on chip to a nanophotonic circuit was demonstrated in this thesis. DBT is a photostable single photon source in the near infrared spectrum at room and at cryogenic temperature, with almost unitary quan-tum yield. In order to protect the molecule against oxidization DBT was embedded in a host matrix – thin Anthracene crystal (DBT:Ac), which increases photostability. Mirror enhanced grating couplers were employed as convenient output ports for ridge Si3N4 waveguide to detect single photons emitted from integrated Dibenzoterrylene (DBT) molecules at room temperature. The coupling ports were designed for waveguide structures on transparent silica substrates for light extraction from the chip backside. These grating ports were employed to read out optical signal from waveguides designed for single-mode operation at λ=785 nm. DBT molecule was coupled evanescently to the waveguide, and upon excitation of isolated single molecule, emitted single photon signal was carried inside the waveguide to the outcou-pling regions. Using a Hanbury Brown and Twiss setup pronounced antibunching dip was read out from a single molecule via the grating couplers, which confirms the quantum nature of the outcoupled fluorescent light. Simulated and measured transmission coupling efficiency of sin-gle photon emission into the waveguide mode equals =42%. The results were published in P. Lombardi*, A. P. Ovvyan*, S. Pazzagli, G. Mazzamuto, G. Kewes, O. Neitzke, N. Gruhler, O. Benson, W. H. P. Pernice, F. S. Cataliotti, and C. Toninelli. Photostable Molecules on Chip: Integrated Sources of Nonclassical Light. ACS Photonics 2018, 5, 126−132, DOI: 10.1021/acsphotonics.7b00521. * P. Lombardi and A. P. Ovvyan contributed equally to this work. Engineered nanophotonic elements integrated in optical circuits with coupled single photon emitter on chip allow simultaneously to enhance the emitted light by coupling it into resonant PhC cavity modes, to spatially separate the excitation light from the enhanced single photon emission and to filter out pump light. Enhancement of the emission rate leads to a sig-nificant increase of the coupling efficiency into cavity. Beforehand performed simulations were an essential step in order to design, build and optimize the architecture of the nanophotonic devices. Local Density of States enhancement computation was especially necessary to pre-cisely determine optimized position of the source on PhC cavity region to obtain maximum enhancement of the emission rate. To evaluate transmission coupling efficiency of emitted light into the cavity (β-factor), an extra round of simulations was performed. The integrated photonic elements investigated and optimized in this Thesis, will be further employed for the realization of hybrid photonic circuits with integrated single photon sources: silicon-vacancy, nitrogen-vacancy centers in diamond as well as single organic molecule and semiconducting single-walled carbon nanotubes.
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Книги з теми "Integrated nanophotonic circuit"

1

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

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2

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

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3

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

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4

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

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5

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

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6

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

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7

Nicolescu, Gabriela, Mahdi Nikdast, and Sébastien Le Beux. Photonic Interconnects for Computing Systems: Understanding and Pushing Design Challenges. River Publishers, 2022.

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8

Nicolescu, Gabriela, Mahdi Nikdast, and Sébastien Le Beux. Photonic Interconnects for Computing Systems: Understanding and Pushing Design Challenges. River Publishers, 2022.

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9

Nicolescu, Gabriela, Mahdi Nikdast, and Sébastien Le Beux. Photonic Interconnects for Computing Systems: Understanding and Pushing Design Challenges. River Publishers, 2022.

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Photonic Interconnects for Computing Systems: Understanding and Pushing Design Challenges. River Publishers, 2017.

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Частини книг з теми "Integrated nanophotonic circuit"

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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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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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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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Анотація:
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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Zalevsky, Zeev, and Ibrahim Abdulhalim. "Silicon Photonic Modulation Circuitry." In Integrated Nanophotonic Devices, 83–101. Elsevier, 2014. http://dx.doi.org/10.1016/b978-0-323-22862-6.00003-7.

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Zalevsky, Zeev, and Ibrahim Abdulhalim. "Integrated Nanoplasmonic Logic Circuitry." In Integrated Nanophotonic Devices, 247–59. Elsevier, 2014. http://dx.doi.org/10.1016/b978-0-323-22862-6.00007-4.

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Zalevsky, Zeev, and Ibrahim Abdulhalim. "Silicon Photonic Modulation Circuitry." In Integrated Nanophotonic Devices, 79–97. Elsevier, 2010. http://dx.doi.org/10.1016/b978-1-4377-7848-9.00003-3.

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Shinya, A., T. Tanabe, E. Kutamochi, H. Taniyama, S. Kawanishi, and M. Notomi. "Functional Devices in Photonic Crystals for Future Photonic Integrated Circuits." In VLSI Micro- and Nanophotonics, 7‚Äì1–7‚Äì16. CRC Press, 2010. http://dx.doi.org/10.1201/b10371-13.

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Benisty, Henri, Jean-Jacques Greffet, and Philippe Lalanne. "From nanophotonics to devices." In Introduction to Nanophotonics, 573–602. Oxford University Press, 2022. http://dx.doi.org/10.1093/oso/9780198786139.003.0020.

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Анотація:
The chapter reviews selected key technologies for nanophotonics applications in passive or emitting devices. The chapter introduces the scientific principles and the figures of merit of these devices, in which guides, gratings, plasmonic systems, periodic guides of previous chapters are the ingredients. It details the issue of sensing, a very heuristic topic. It then provides clues for a practical, applications-based approach to the design and operation of integrated photonic circuits and their electro-optic functions. In the area of active devices, it deals with the factors that determine the device efficiency. For edge-emitting lasers, it shows how guide and gratings are assembled in the emblematic DFB laser diodes. Vertical emitting lasers (VCSELs) are also discussed, connecting their structure to fundamentals of light-matter interaction and to periodicity. The important issue of light extraction is eventually revisited across several kinds of devices, LEDs of course, but also other specialized emitting systems.
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Asakawa, Kiyoshi, Nobuhiko Ozaki, Shunsuke Ohkouchi, Yoshimasa Sugimoto, and Naoki Ikeda. "Advanced Growth Techniques of InAs-system Quantum Dots for Integrated Nanophotonic Circuits." In Handbook of Self Assembled Semiconductor Nanostructures for Novel Devices in Photonics and Electronics, 529–51. Elsevier, 2008. http://dx.doi.org/10.1016/b978-0-08-046325-4.00017-7.

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Тези доповідей конференцій з теми "Integrated nanophotonic circuit"

1

Rahman, Anis. "Dendrimer Based NanoPhotonic Integrated Circuit for Terahertz Computing and Sensing." In Organic Materials and Devices for Displays and Energy Conversion. Washington, D.C.: OSA, 2007. http://dx.doi.org/10.1364/omd.2007.otub3.

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Van Campenhout, J., P. Rojo-Romeo, P. Regreny, C. Seassal, D. Van Thourhout, L. Di Cioccio, J. M. Fedeli, and R. Baets. "Optimization of Electrically Pumped Microdisk Lasers Integrated with a Nanophotonic SOI Waveguide Circuit." In Integrated Photonics and Nanophotonics Research and Applications. Washington, D.C.: OSA, 2007. http://dx.doi.org/10.1364/ipnra.2007.itug3.

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Tassaert, M., S. Keyvaninia, D. Van Thourhout, W. M. J. Green, Y. Vlasov, and G. Roelkens. "A nanophotonic InP/InGaAlAs optical amplifier integrated on a SOI waveguide circuit." In 2011 ICO International Conference on Information Photonics (IP). IEEE, 2011. http://dx.doi.org/10.1109/ico-ip.2011.5953699.

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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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Melloni, A., M. Carminati, A. Annoni, F. Morichetti, P. Ciccarella, S. Grillanda, G. Ferrari, M. Sorel, and M. Sampietro. "Light-Path Tracking and Circuit Reconfiguration of Silicon Photonic Circuits Assisted by Non-Invasive Optical Probes." In Integrated Photonics Research, Silicon and Nanophotonics. Washington, D.C.: OSA, 2015. http://dx.doi.org/10.1364/iprsn.2015.it4a.2.

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Roels, J., B. Maes, R. Baets, and D. Van Thourhout. "Integrated optomechanical circuits." In Integrated Photonics Research, Silicon and Nanophotonics. Washington, D.C.: OSA, 2010. http://dx.doi.org/10.1364/iprsn.2010.imf4.

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Van Campenhout, J., P. Rojo-Romeo, P. Regreny, C. Seassal, D. Van Thourhout, L. Di Cioccio, C. Lagahe, J. M. Fedeli, and R. Baets. "Electrically injected InP microdisk lasers integrated with nanophotonic SOI circuits." In Integrated Optoelectronic Devices 2008, edited by Joel A. Kubby and Graham T. Reed. SPIE, 2008. http://dx.doi.org/10.1117/12.767958.

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Thylen, Lars. "Status and prospects of integrated nanophotonics circuits." 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.2008.4688868.

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Dapkus, P. D., and J. D. O'Brien. "Meso- and nanophotonic devices for integrated photonic circuits." In 61st Device Research Conference. IEEE, 2003. http://dx.doi.org/10.1109/drc.2003.1226900.

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Zhao, Mengdi, and Kejie Fang. "Nanophotonic integrated circuits with 1% single-photon nonlinearity." In Nonlinear Optics. Washington, D.C.: OSA, 2021. http://dx.doi.org/10.1364/nlo.2021.nw2b.1.

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Звіти організацій з теми "Integrated nanophotonic circuit"

1

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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