Relevant bibliographies by topics / Nanophotonics device fabrication

Academic literature on the topic 'Nanophotonics device fabrication'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Nanophotonics device fabrication"

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Zhao, Dong, Zhelin Lin, Wenqi Zhu, Henri J. Lezec, Ting Xu, Amit Agrawal, Cheng Zhang, and Kun Huang. "Recent advances in ultraviolet nanophotonics: from plasmonics and metamaterials to metasurfaces." Nanophotonics 10, no. 9 (May 24, 2021): 2283–308. http://dx.doi.org/10.1515/nanoph-2021-0083.

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Abstract Nanophotonic devices, composed of metals, dielectrics, or semiconductors, enable precise and high-spatial-resolution manipulation of electromagnetic waves by leveraging diverse light–matter interaction mechanisms at subwavelength length scales. Their compact size, light weight, versatile functionality and unprecedented performance are rapidly revolutionizing how optical devices and systems are constructed across the infrared, visible, and ultraviolet spectra. Here, we review recent advances and future opportunities of nanophotonic elements operating in the ultraviolet spectral region, which include plasmonic devices, optical metamaterials, and optical metasurfaces. We discuss their working principles, material platforms, fabrication, and characterization techniques, followed by representative device applications across various interdisciplinary areas such as imaging, sensing and spectroscopy. We conclude this review by elaborating on future opportunities and challenges for ultraviolet nanophotonic devices.
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Ledentsov, Nikolay N., Nikolay Ledentsov, Mikel Agustin, Joerg-R. Kropp, and Vitaly A. Shchukin. "Application of nanophotonics to the next generation of surface-emitting lasers." Nanophotonics 6, no. 5 (February 21, 2017): 813–29. http://dx.doi.org/10.1515/nanoph-2016-0173.

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AbstractNovel trends and concepts in the design and fabrication of vertical cavity surface-emitting lasers (VCSELs) and their integration in optical networks and implementation in integrated photonics applications are discussed. To serve these goals and match the growing bandwidth demands, significant changes are to be implemented in the device design. New lateral leakage-mediated single-mode VCSELs, including both devices confined by oxide layers and those confined by alloy-intermixed regions, are likely to be good candidates for light sources for the data networks of the future. An overview of the records in VCSEL transmission distances and transmission speeds is discussed in this context.
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CHAN, M. Y., and P. S. LEE. "FABRICATION OF SILICON NANOCRYSTALS AND ITS ROOM TEMPERATURE LUMINESCENCE EFFECTS." International Journal of Nanoscience 05, no. 04n05 (August 2006): 565–70. http://dx.doi.org/10.1142/s0219581x06004802.

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Silicon ( Si ) nanocrystals have been considered a good candidate for flash memory device and nanophotonic applications. The fabrication of nanocrystal memory is to form uniform, small size and high density quantum dots. In this study, nanometer-scale silicon quantum dots have been fabricated on ultrathin silicon oxide layer using amorphous silicon (a- Si ) deposition followed by various annealing treatments. The a- Si layers were crystallized using furnace annealing, laser annealing and rapid thermal annealing (RTA). After annealing to form nanometer-sized crystallites, silicon wet etch was carried out to isolate the nanocrystals. The size, uniformity and density of the nanocrystals were successfully controlled by different annealing treatments. The mean dot height and mean dot diameter is 1–5 nm and 2–5 nm, respectively. Lateral growth of the silicon dots was further controlled by systemic variations of the annealing conditions. It is found that the annealed a- Si films exhibit room temperature visible photoluminescence (PL) resulting from the formation of nanometer-sized crystallites. Selective wet etch and Secco-etch treatment increased the PL efficiency that is useful for nanophotonics applications. The feasibility of quantum dot formation using ultra thin amorphous Si films is demonstrated in this work.
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Rani, Dipti, Oliver Roman Opaluch, and Elke Neu. "Recent Advances in Single Crystal Diamond Device Fabrication for Photonics, Sensing and Nanomechanics." Micromachines 12, no. 1 (December 30, 2020): 36. http://dx.doi.org/10.3390/mi12010036.

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In the last two decades, the use of diamond as a material for applications in nanophotonics, optomechanics, quantum information, and sensors tremendously increased due to its outstanding mechanical properties, wide optical transparency, and biocompatibility. This has been possible owing to advances in methods for growth of high-quality single crystal diamond (SCD), nanofabrication methods and controlled incorporation of optically active point defects (e.g., nitrogen vacancy centers) in SCD. This paper reviews the recent advances in SCD nano-structuring methods for realization of micro- and nano-structures. Novel fabrication methods are discussed and the different nano-structures realized for a wide range of applications are summarized. Moreover, the methods for color center incorporation in SCD and surface treatment methods to enhance their properties are described. Challenges in the upscaling of SCD nano-structure fabrication, their commercial applications and future prospects are discussed.
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Leykam, Daniel, and Luqi Yuan. "Topological phases in ring resonators: recent progress and future prospects." Nanophotonics 9, no. 15 (September 25, 2020): 4473–87. http://dx.doi.org/10.1515/nanoph-2020-0415.

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AbstractTopological photonics has emerged as a novel paradigm for the design of electromagnetic systems from microwaves to nanophotonics. Studies to date have largely focused on the demonstration of fundamental concepts, such as nonreciprocity and waveguiding protected against fabrication disorder. Moving forward, there is a pressing need to identify applications where topological designs can lead to useful improvements in device performance. Here, we review applications of topological photonics to ring resonator–based systems, including one- and two-dimensional resonator arrays, and dynamically modulated resonators. We evaluate potential applications such as quantum light generation, disorder-robust delay lines, and optical isolation, as well as future research directions and open problems that need to be addressed.
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Cheng, Yan, Ebuka S. Arinze, Nathan Palmquist, and Susanna M. Thon. "Advancing colloidal quantum dot photovoltaic technology." Nanophotonics 5, no. 1 (June 1, 2016): 31–54. http://dx.doi.org/10.1515/nanoph-2016-0017.

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Abstract Colloidal quantum dots (CQDs) are attractive materials for solar cells due to their low cost, ease of fabrication and spectral tunability. Progress in CQD photovoltaic technology over the past decade has resulted in power conversion efficiencies approaching 10%. In this review, we give an overview of this progress, and discuss limiting mechanisms and paths for future improvement in CQD solar cell technology.We briefly summarize nanoparticle synthesis and film processing methods and evaluate the optoelectronic properties of CQD films, including the crucial role that surface ligands play in materials performance. We give an overview of device architecture engineering in CQD solar cells. The compromise between carrier extraction and photon absorption in CQD photovoltaics is analyzed along with different strategies for overcoming this trade-off. We then focus on recent advances in absorption enhancement through innovative device design and the use of nanophotonics. Several light-trapping schemes, which have resulted in large increases in cell photocurrent, are described in detail. In particular, integrating plasmonic elements into CQD devices has emerged as a promising approach to enhance photon absorption through both near-field coupling and far-field scattering effects. We also discuss strategies for overcoming the single junction efficiency limits in CQD solar cells, including tandem architectures, multiple exciton generation and hybrid materials schemes. Finally, we offer a perspective on future directions for the field and the most promising paths for achieving higher device efficiencies.
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Kadinskaya, Svetlana A., Valeriy M. Kondratev, Ivan K. Kindyushov, Olga Yu Koval, Dmitry I. Yakubovsky, Alexey Kusnetsov, Alexey I. Lihachev, et al. "Deep-Level Emission Tailoring in ZnO Nanostructures Grown via Hydrothermal Synthesis." Nanomaterials 13, no. 1 (December 23, 2022): 58. http://dx.doi.org/10.3390/nano13010058.

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Zinc oxide (ZnO) nanostructures are widely used in various fields of science and technology due to their properties and ease of fabrication. To achieve the desired characteristics for subsequent device application, it is necessary to develop growth methods allowing for control over the nanostructures’ morphology and crystallinity governing their optical and electronic properties. In this work, we grow ZnO nanostructures via hydrothermal synthesis using surfactants that significantly affect the growth kinetics. Nanostructures with geometry from nanowires to hexapods are obtained and studied with photoluminescence (PL) spectroscopy. Analysis of the photoluminescence spectra demonstrates pronounced exciton on a neutral donor UV emission in all of the samples. Changing the growth medium chemical composition affects the emission characteristics sufficiently. Apart the UV emission, nanostructures synthesized without the surfactants demonstrate deep-level emission in the visible range with a peak near 620 nm. Structures synthesized with the use of sodium citrate exhibit emission peak near 520 nm, and those with polyethylenimine do not exhibit the deep-level emission. Thus, we demonstrate the correlation between the hydrothermal growth conditions and the obtained ZnO nanostructures’ optical properties, opening up new possibilities for their precise control and application in nanophotonics, UV–Vis and white light sources.
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Meng, Qi, Xingqiao Chen, Wei Xu, Zhihong Zhu, Xiaodong Yuan, and Jianfa Zhang. "High Q Resonant Sb2S3-Lithium Niobate Metasurface for Active Nanophotonics." Nanomaterials 11, no. 9 (September 13, 2021): 2373. http://dx.doi.org/10.3390/nano11092373.

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Phase change materials (PCMs) are attracting more and more attentions as enabling materials for tunable nanophotonics. They can be processed into functional photonic devices through customized laser writing, providing great flexibility for fabrication and reconfiguration. Lithium Niobate (LN) has excellent nonlinear and electro-optical properties, but is difficult to process, which limits its application in nanophotonic devices. In this paper, we combine the emerging low-loss phase change material Sb2S3 with LN and propose a new type of high Q resonant metasurface. Simulation results show that the Sb2S3-LN metasurface has extremely narrow linewidth of 0.096 nm and high quality (Q) factor of 15,964. With LN as the waveguide layer, strong nonlinear properties are observed in the hybrid metasurface, which can be employed for optical switches and isolators. By adding a pair of Au electrodes on both sides of the LN, we can realize dynamic electro-optical control of the resonant metasurface. The ultra-low loss of Sb2S3, and its combination with LN, makes it possible to realize a new family of high Q resonant metasurfaces for actively tunable nanophotonic devices with widespread applications including optical switching, light modulation, dynamic beam steering, optical phased array and so on.
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Chin, Lip Ket, Yuzhi Shi, and Ai-Qun Liu. "Optical Forces in Silicon Nanophotonics and Optomechanical Systems: Science and Applications." Advanced Devices & Instrumentation 2020 (October 26, 2020): 1–14. http://dx.doi.org/10.34133/2020/1964015.

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Light-matter interactions have been explored for more than 40 years to achieve physical modulation of nanostructures or the manipulation of nanoparticle/biomolecule. Silicon photonics is a mature technology with standard fabrication techniques to fabricate micro- and nano-sized structures with a wide range of material properties (silicon oxides, silicon nitrides, p- and n-doping, etc.), high dielectric properties, high integration compatibility, and high biocompatibilities. Owing to these superior characteristics, silicon photonics is a promising approach to demonstrate optical force-based integrated devices and systems for practical applications. In this paper, we provide an overview of optical force in silicon nanophotonic and optomechanical systems and their latest technological development. First, we discuss various types of optical forces in light-matter interactions from particles or nanostructures. We then present particle manipulation in silicon nanophotonics and highlight its applications in biological and biomedical fields. Next, we discuss nanostructure mechanical modulation in silicon optomechanical devices, presenting their applications in photonic network, quantum physics, phonon manipulation, physical sensors, etc. Finally, we discuss the future perspective of optical force-based integrated silicon photonics.
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Melzer, Jeffrey E., and Euan McLeod. "3D Nanophotonic device fabrication using discrete components." Nanophotonics 9, no. 6 (June 6, 2020): 1373–90. http://dx.doi.org/10.1515/nanoph-2020-0161.

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AbstractThree-dimensional structure fabrication using discrete building blocks provides a versatile pathway for the creation of complex nanophotonic devices. The processing of individual components can generally support high-resolution, multiple-material, and variegated structures that are not achievable in a single step using top-down or hybrid methods. In addition, these methods are additive in nature, using minimal reagent quantities and producing little to no material waste. In this article, we review the most promising technologies that build structures using the placement of discrete components, focusing on laser-induced transfer, light-directed assembly, and inkjet printing. We discuss the underlying principles and most recent advances for each technique, as well as existing and future applications. These methods serve as adaptable platforms for the next generation of functional three-dimensional nanophotonic structures.
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Dissertations / Theses on the topic "Nanophotonics device fabrication"

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Taverne, Mike. "Modelling and fabrication of nanophotonics devices." Thesis, University of Bristol, 2017. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.715771.

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Dahal, Rajendra Prasad. "Fabrication and characterization of III-nitride nanophotonic devices." Diss., Manhattan, Kan. : Kansas State University, 2009. http://hdl.handle.net/2097/2198.

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Chamanzar, Maysamreza. "Hybrid nanoplasmonic-nanophotonic devices for on-chip biochemical sensing and spectroscopy." Diss., Georgia Institute of Technology, 2012. http://hdl.handle.net/1853/50145.

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Hybrid plasmonic-photonic structures were introduced as novel platforms for on-chip biochemical sensing and spectroscopy. By appropriate coupling of photonic and plasmonic modes, a hybrid architecture was realized that can benefit from the advantages of integrated photonics such as the low propagation loss, ultra-high Q modes, and robustness, as well as the advantages of nanoplasmonics such as extreme light localization, large sensitivities, and ultra-high field enhancements to bring about unique performance advantages for efficient on-chip sensing. These structures are highly sensitive and can effectively interact with the target biological and chemical molecules. It was shown that interrogation of single plasmonic nanoparticles is possible using a hybrid waveguide and microresonator-based structure, in which light is efficiently coupled from photonic structures to the integrated plasmonic structures. The design, implementation, and experimental demonstration of hybrid plasmonic-photonic structures for lab-on-chip biochemical sensing applications were discussed. The design goal was to achieve novel, robust, highly efficient, and high-throughput devices for on-chip sensing. The sensing scenarios of interest were label-free refractive index sensing and SERS. Nanofabrication processes were developed to realize the hybrid plasmonic-photonic structures. Silicon nitride was used as the material platform to realize the integrated photonic structure, and gold was used to realize plasmonic nanostructures. Special optical characterization setups were designed and implemented to test the performance of these nanoplasmonic and nanophotonic structures. The integration of the hybrid plasmonic-photonic structures with microfluidics was also optimized and demonstrated. The hybrid plasmonic-photonic-fluidic structures were used to detect different analytes at different concentrations. A complete course of research from design, fabrication, and characterization to demonstration of sensing applications was conducted to realize nanoplasmonic and integrated photonic structures. The novel structures developed in this research can open up new potentials for biochemical sensors with advanced on-chip functionalities and enhanced performances.
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Wei, Jhih-Ci, and 韋志棋. "Nanophotonics Plasmonic Device Fabrication." Thesis, 2008. http://ndltd.ncl.edu.tw/handle/62460356224127907116.

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碩士
國立臺灣大學
物理研究所
96
In this thesis, we use the helium-Neon laser with wavelength 633nm, and focus the laser to phase-change thin film Ge2Sb2Te5 by high magnification and high number aperture oil objective lens(100x, NA:1.4). By controlling the high precision piezo nano-stage, we can fabricate any crystalline two-dimensional structure. The experimental results shows that we can fabricate the circle array, chiral structure, 2-D spiral structure, and checker board structure. By using the same experimental setup, we replace the red light laser with femto-second pulse laser. We can use non-linear optical effect ,two-photon absorption. Because the light source have good three dimensional spatial selectivity for commercial photo-polymerization resin, we could manufacture any three dimensional structure. We also can improve the material to fabricate the two-dimensional metallic structure. It is a challenge to fabricate the three dimensional metallic structure. This method can apply to the research of Plasmonic Meta-material , and maybe it is a tool to fabricate the commercial plasmonic optical device in the future.
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Chen, Charlton J. "Precision Tuning of Silicon Nanophotonic Devices through Post-Fabrication Processes." Thesis, 2011. https://doi.org/10.7916/D8MS40QG.

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This thesis investigates ways of improving the performance of fundamental silicon nanophotonic devices through post-fabrication processes. These devices include numerous optical resonator designs as well as slow-light waveguides. Optical resonators are used to confine photons both spatially and temporally. In recent years, there has been much research, both theoretical and experimental, into improving the design of optical resonators. Improving these devices through fabrication processes has generally been less studied. Optical waveguides are used to guide the flow of photons over chip-level distances. Slow-light waveguides have also been studied by many research groups in recent years and can applied to an increasingly wide-range of applications. The work can be divided into several parts: Chapter 1 is an introduction to the field of silicon photonics as well as an overview of the fabrication, experimental and computational techniques used throughout this work. Chapters 2, 3 and 4 describe our investigations into the precision tuning of nanophotonic devices using laser-assisted oxidation and atomic layer deposition. Chapters 5 and 6 describe our investigations into improving the sidewall roughness of silicon photonic devices using hydrogen annealing and excimer laser induced melting. Finally, Chapter 7 describes our investigations into the nonlinear properties of lead chalcogenide nanocrystals.
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Books on the topic "Nanophotonics device fabrication"

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service), SpringerLink (Online, ed. Nanophotonic Fabrication: Self-Assembly and Deposition Techniques. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012.

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Yatsui, Takashi. Nanophotonic Fabrication: Self-Assembly and Deposition Techniques. Springer, 2014.

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A, Kemme Shanalyn, ed. Microoptics and nanooptics fabrication. Boca Raton: CRC Press, 2010.

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Feldman, Martin. Nanolithography: The Art of Fabricating Nanoelectronic and Nanophotonic Devices and Systems. Elsevier Science & Technology, 2013.

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Feldman, Martin. Nanolithography: The Art of Fabricating Nanoelectronic and Nanophotonic Devices and Systems. Elsevier Science & Technology, 2017.

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Feldman, M. Nanolithography: The Art of Fabricating Nanoelectronic and Nanophotonic Devices and Systems. Elsevier Science & Technology, 2014.

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Microoptics and Nanooptics Fabrications. CRC, 2009.

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Ohtsu, Motoichi. Progress in Nano-Electro-Optics V: Nanophotonic Fabrications, Devices, Systems, and Their Theoretical Bases. Springer, 2007.

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Ohtsu, Motoichi. Progress in Nano-Electro-Optics V: Nanophotonic Fabrications, Devices, Systems, and Their Theoretical Bases. Springer, 2010.

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Ohtsu, Motoichi. Progress in Nano-Electro-Optics V: Nanophotonic Fabrications, Devices, Systems, and Their Theoretical Bases (Springer Series in Optical Sciences). Springer, 2006.

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Book chapters on the topic "Nanophotonics device fabrication"

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Sharma, Rashi, Stephen M. Kuebler, Christopher N. Grabill, Jennefir L. Digaum, Nicholas R. Kosan, Alexander R. Cockerham, Noel Martinez, and Raymond C. Rumpf. "Fabrication of Functional Nanophotonic Devices via Multiphoton Polymerization." In ACS Symposium Series, 151–71. Washington, DC: American Chemical Society, 2019. http://dx.doi.org/10.1021/bk-2019-1315.ch009.

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Ohtsu, Motoichi. "Nanophotonics: Dressed Photon Technology for Qualitatively Innovative Optical Devices, Fabrication, and Systems." In Progress in Nanophotonics 1, 1–58. Berlin, Heidelberg: Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-17481-0_1.

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Yan, Yongli, and Yong Sheng Zhao. "Design, Fabrication, and Optoelectronic Performance of Organic Building Blocks for Integrated Nanophotonic Devices." In Nano-Optics and Nanophotonics, 181–205. Berlin, Heidelberg: Springer Berlin Heidelberg, 2014. http://dx.doi.org/10.1007/978-3-662-45082-6_8.

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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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Zalevsky, Zeev, and Ibrahim Abdulhalim. "Fabrication Aspects of Integrated Devices." In Integrated Nanophotonic Devices, 103–15. Elsevier, 2014. http://dx.doi.org/10.1016/b978-0-323-22862-6.00004-9.

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Zalevsky, Zeev, and Ibrahim Abdulhalim. "Fabrication Aspects of Integrated Devices." In Integrated Nanophotonic Devices, 99–111. Elsevier, 2010. http://dx.doi.org/10.1016/b978-1-4377-7848-9.00004-5.

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Conference papers on the topic "Nanophotonics device fabrication"

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Joo, Jae Young, Do-Kyun Woo, Sun Sub Park, and Sun-Kyu Lee. "Fabrication of LED based Ultra Slim Optical Pointing Device." In Nanophotonics. IEEE, 2010. http://dx.doi.org/10.1109/omems.2010.5672140.

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Ozaki, Katsuya, Daisuke Akai, Kazuaki Sawada, and Makoto Ishida. "Fabrication and evaluation of piezoelectric drive type 2-axis tilt control device using epitaxial PZT thin film." In Nanophotonics. IEEE, 2010. http://dx.doi.org/10.1109/omems.2010.5672153.

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Higo, Akio, Haibin Wang, Takaya Kubo, Naoto Usami, Yuki Okamoto, Kentaro Yamada, Hiroshi Hegawa, Masakazu Sugiyama, and Yoshio Mita. "Fabrication of PbS quantum dots and silicon device for near-infrared detection." In 2017 International Conference on Optical MEMS and Nanophotonics (OMN). IEEE, 2017. http://dx.doi.org/10.1109/omn.2017.8051438.

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Ohtsu, Motoichi. "Concepts of nanophotonic devices and fabrications." In 2007 IEEE/LEOS International Conference on Optical MEMS and Nanophotonics. IEEE, 2007. http://dx.doi.org/10.1109/omems.2007.4373809.

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Grutter, Karen E., Anthony M. Yeh, Susant K. Patra, and Ming C. Wu. "A new fabrication technique for integrating silica optical devices and MEMS." In Nanophotonics. IEEE, 2010. http://dx.doi.org/10.1109/omems.2010.5672199.

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Erickson, David, Sudeep Mandal, Allen Yang, Julie Goddard, and Bernardo Cordovez. "Optofluidics: Fluidics Enabling Optics and Optics Enabling Fluidics." In ASME 2008 First International Conference on Micro/Nanoscale Heat Transfer. ASMEDC, 2008. http://dx.doi.org/10.1115/mnht2008-52025.

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Optical devices which incorporate liquids as a fundamental part of the structure can be traced at least as far back as the 18th century where rotating pools of mercury were proposed as a simple technique to create smooth mirrors for use in reflecting telescopes. Modern microfluidic and nanofluidics has enabled the development of a present day equivalent of such devices centered on the marriage of fluidics and optics which we refer to as “Optofluidics.” In this review paper we will present an overview of our approach to the development of three different optofluidic devices. In the first of these we will demonstrate how the fusion of novel nanophotonic structures with micro- and nanofluidic networks can be used to perform ultrasensitive, label free biomolecular analysis. This will be done in the context of our newly developed devices for screening of Dengue and Influenza virus RNA. For the second class of device I will discuss and demonstrate how optical forces (scattering, adsorption and polarization) in solid and liquid core nanophotonic structures can be used to drive novel microfluidic processes. Some of the advanced analytical, numerical and experimental techniques used to investigate and design these systems will be discussed as well as issues relating to integration and their fabrication.
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Kuebler, Stephen M., Chun Xia, Rashi Sharma, Jennefir L. Digaum, Noel P. Martinez, Cesar L. Valle, and Raymond C. Rumpf. "Fabrication of functional nanophotonic devices by multiphoton lithography." In Organic Photonic Materials and Devices XXI, edited by Christopher E. Tabor, François Kajzar, and Toshikuni Kaino. SPIE, 2019. http://dx.doi.org/10.1117/12.2508675.

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Scherer, Axel, Uday Khankhoje, Tom Baehr-Jones, and Se-Heon Kim. "The Evolution from III-V Opto-Electronics to Silicon Nanophotonics and Vertical Cavity Lasers to Photonic Crystal and Surface Plasmon Devices." In Optical Fabrication and Testing. Washington, D.C.: OSA, 2010. http://dx.doi.org/10.1364/oft.2010.ima1.

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Ng, Doris K. T., Kim-Peng Lim, Qian Wang, Jing Pu, Kun Tang, Yicheng Lai, Chee-Wei Lee, and Seng-Tiong Ho. "Fabrication of low-loss silicon nanophotonic waveguide for photonic device integration." In SPIE OPTO, edited by Joel Kubby and Graham T. Reed. SPIE, 2013. http://dx.doi.org/10.1117/12.2002791.

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Yatsui, Takashi, Wataru Nomura, and Motoichi Ohtsu. "Size- and position-controlled nano-scale fabrication for nanophotonic devices." In Optics & Photonics 2005, edited by Mark I. Stockman. SPIE, 2005. http://dx.doi.org/10.1117/12.614259.

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Reports on the topic "Nanophotonics device fabrication"

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Fainman, Y. Advanced Fabrication and Characterization of Quantum and Nanophotonic Devices and Systems. Fort Belvoir, VA: Defense Technical Information Center, June 2004. http://dx.doi.org/10.21236/ada428546.

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