Literatura académica sobre el tema "PLASMONIC NANOGRATINGS"
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Artículos de revistas sobre el tema "PLASMONIC NANOGRATINGS"
Das, Narottam, Ayman Karar, Chee Leong Tan, Mikhail Vasiliev, Kamal Alameh y Yong Tak Lee. "Metal-semiconductor-metal (MSM) photodetectors with plasmonic nanogratings*". Pure and Applied Chemistry 83, n.º 11 (7 de julio de 2011): 2107–13. http://dx.doi.org/10.1351/pac-con-11-01-13.
Texto completoZhao, Bo, Zhenfen Huang, Jianjun Yang, Lei Zhang, Rajagopal S. Joshya y Chunlei Guo. "A High-Efficiency Multispectral Filter Based on Plasmonic Hybridization between Two Cascaded Ultrathin Nanogratings". Molecules 24, n.º 11 (28 de mayo de 2019): 2038. http://dx.doi.org/10.3390/molecules24112038.
Texto completoFiroozi, Arezoo y Ahmad Mohammadi. "Design of plasmonic backcontact nanogratings for broadband and polarization-insensitive absorption enhancement in thin-film solar cell". International Journal of Modern Physics B 29, n.º 17 (23 de junio de 2015): 1550111. http://dx.doi.org/10.1142/s0217979215501118.
Texto completoSubramanian, Senthil, Kamal Kumar y Anuj Dhawan. "Palladium-coated narrow groove plasmonic nanogratings for highly sensitive hydrogen sensing". RSC Advances 10, n.º 7 (2020): 4137–47. http://dx.doi.org/10.1039/c9ra08101a.
Texto completoBhardwaj, Priyanka, Manidipa Roy y Sanjay Kumar Singh. "Gold Coated VO2 Nanogratings Based Plasmonic Switches". Trends in Sciences 19, n.º 1 (1 de enero de 2022): 1721. http://dx.doi.org/10.48048/tis.2022.1721.
Texto completoLi, Shulei, Mingcheng Panmai, Shaolong Tie, Yi Xu, Jin Xiang y Sheng Lan. "Regulating disordered plasmonic nanoparticles into polarization sensitive metasurfaces". Nanophotonics 10, n.º 5 (15 de febrero de 2021): 1553–63. http://dx.doi.org/10.1515/nanoph-2020-0651.
Texto completoFerrando, Giulio, Matteo Gardella, Matteo Barelli, Debasree Chowdhury, Pham Duy Long, Nguyen Si Hieu, Maria Caterina Giordano y Francesco Buatier de Mongeot. "Plasmonic and 2D-TMD nanoarrays for large-scale photon harvesting and enhanced molecular photo-bleaching". EPJ Web of Conferences 266 (2022): 09003. http://dx.doi.org/10.1051/epjconf/202226609003.
Texto completoDas, Narottam, Farzaneh Fadakar Masouleh y Hamid Reza Mashayekhi. "A Comprehensive Analysis of Plasmonics-Based GaAs MSM-Photodetector for High Bandwidth-Product Responsivity". Advances in OptoElectronics 2013 (24 de septiembre de 2013): 1–10. http://dx.doi.org/10.1155/2013/793253.
Texto completoPalinski, Timothy J., Brian E. Vyhnalek, Gary W. Hunter, Amogha Tadimety y John X. J. Zhang. "Mode Switching With Waveguide-Coupled Plasmonic Nanogratings". IEEE Journal of Selected Topics in Quantum Electronics 27, n.º 1 (enero de 2021): 1–10. http://dx.doi.org/10.1109/jstqe.2020.3019023.
Texto completoKudryashov, Sergey, Alexey Rupasov, Mikhail Kosobokov, Andrey Akhmatkhanov, George Krasin, Pavel Danilov, Boris Lisjikh et al. "Hierarchical Multi-Scale Coupled Periodical Photonic and Plasmonic Nanopatterns Inscribed by Femtosecond Laser Pulses in Lithium Niobate". Nanomaterials 12, n.º 23 (4 de diciembre de 2022): 4303. http://dx.doi.org/10.3390/nano12234303.
Texto completoTesis sobre el tema "PLASMONIC NANOGRATINGS"
Hong, Koh Yiin. "Label-free plasmonic detection using nanogratings fabricated by laser interference lithography". Thesis, Plasmonics, 2017. http://hdl.handle.net/1828/7849.
Texto completoGraduate
2018-02-17
Vangheluwe, Marie. "Etude de la structuration laser femtoseconde multi-échelle de verres d'oxydes dopés à l'argent". Thesis, Bordeaux, 2015. http://www.theses.fr/2015BORD0370/document.
Texto completoFemtosecond direct laser writing (fs-DLW) of oxide glasses is a growing researchand development area. It is also increasingly used in the high-tech industry thanks to its simpleimplementation and numerous possible applications emerging from the photonic componentsmanufacture. Indeed, an ultra-short focused beam in a transparent material reaches a sufficientintensity to 3D modify the material on micro- or nanometer scale. However, the fs-DLW regimesat such high intensity are not completely understood, and the materials, already used, are notperfectly adapted for new photonics applications. This research work aims to provide answersto those open questions. This thesis is based on two thrusts. The first one addresses the issueof the glass surface DLW with fs pulses which lead to self organized periodic structures. Theinfluence of photosensitive doping ions and irradiation parameters are studied to support theincubation model for nanogratings surface formation. This study allows the control of theseperiodic nanostructures for further applications. The second thrusts deals with localized volumecrystallization. Several glassy matrices with various silver oxide doping have been studied tounderstand the mechanisms of silver nanoparticles (Ag-NPs) precipitation. This workdemonstrates the link between the physical chemistry of the glass and the non-equilibriumthermodynamic state during fs-DLW to influence nucleation and growth conditions of Ag-NPs.These results are compared to models that describe the optical responses of plasmonicbehavior. This research opens on new approaches and prospects for applications andunderstandings of fs-DLW of novel photonic bricks
JALAL, VIPUL SINGH. "DESIGN & MODELLING OF SYMMETRIC AND ASYMMETRIC PLASMONIC NANOGRATINGS FOR CHEMICAL/BIOLOGICAL SENSING". Thesis, 2019. http://dspace.dtu.ac.in:8080/jspui/handle/repository/17055.
Texto completoKUO, PING-HONG y 郭炳宏. "Analysis of Dielectric Nanograting Coupled Surface Plasmon Resonance Sensor Using Back-Side Incident Light". Thesis, 2018. http://ndltd.ncl.edu.tw/handle/r4myk3.
Texto completo國立虎尾科技大學
光電工程系光電與材料科技碩士班
106
This paper proposes a back-side incident grating coupled structure that can be fabricated using nanoimprint technology. This component has a flat surface and is suitable for sensing the attachment properties of biological cells. We also compare this component with the conventional front-side incident grating coupled structure and analyze the characteristics and sensitivity of the intensity and phase detection of these two different grating coupled surface plasmon resonance elements as sensors. The simulation results show that the sensitivity performance of these two sensors is similar. For the back-side incident sensor, the light will not pass through the material under test during sensing. Besides, the surface is a flat structure, comparing with the grating surface, there will be no surface profile effect when the material under test is attached to the component. We used a low-refractive-index material as the grating structure and it is fabricated on the substrate by nanoimprint technology. Then, a layer of titanium dioxide (TiO2) is sputtered on the surface. The film is combined with a sol-gel method to deposit a titanium dioxide (TiO2) solution on the grating, and finally a layer of gold (Au) is evaporated to form a surface plasma resonance element structure. In order to detect phase changes, we use heterodyne interference technology to match the phase change of the phase-locked amplifier recording component, and use Labview automation program to combine automatic measurement with stepper motor, optical power meter, lock-in amplifier and computer.
Lee, Wei-Hang y 李瑋航. "Development of Label-Free Optical Immunoassay Platform Integrating a Nanofluidic Preconcentrator with a PeriodicMetallic Nanograting Surface Plasmon Resonance Sensor". Thesis, 2016. http://ndltd.ncl.edu.tw/handle/74399476685836495547.
Texto completo國立臺灣大學
生醫電子與資訊學研究所
104
In the field of bio microelectromechanical systems (bio MEMS), detection of the low-abundance analytes without labelling is challenging because of difficulties of integration of preconcentration and label free sensing. Previously, an electrokinetic trapping (EKT)-based nanofluidic preconcentrator had been reported for providing a million-fold concentration factors that enable the validation of concentration process and the detection of trace and fluorescence-labelled analytes. However, the use of fluorescence-labelled analytes has suffered several disadvantages, e.g., additional sample preparation in an experimental workflow, high cost of labeling reagents, and difficulty in analyzing trace analytes. To monitor the concentration process without labelling, our group has presented a real-time dual loop electric current measurement system for label-free EKT-based nanofluidic preconcentrator. In this work, we further demonstrated a label-free biosensing platform by integrating a label-free nanofluidic preconcentrator with label-free surface plasma resonance(SPR) sensors. Bio molecular sample preconcentration was realized by a preconcentrator consisted of two microchannels, a concentration channel and a buffer channel, cast in Polydimethylsiloxane (PDMS) and a porous membrane (Nafion). The nanograting SPR sensor was fabricated by e-beam lithography, e-gun evaporation followed by the lift-off process. After glass-based SPR sensors and PDMS microchannels were fabricated, we patterned Nafion membrane at a specific position adjacent to the SPR sensor by using a microflow patterning method. Finally, PDMS-based microchannels were bonded to a glass patterned with Nafion and two square SPR sensors via bonding technique with oxygen plasma treatment. Recently, a 20 ng/ml Bovine serum albumin (BSA) in PBS was pumped into the platform, and was detected by SPR sensor with a red-shifted value of 0.42 nm. After ten minutes of preconcentration, 20 ng/ml BSA in PBS was detected with a red-shifted value of 5.33 nm. Comparing the references of the red-shifted values at different concentrations of BSA established in advance, the red-shifted value (5 nm) of 20 ng/ml BSA in PBS after preconcentration is the same as the red-shifted value of 200 μg/ml BSA in PBS. Hence, the preconcentration factor in this label-free platform was then determined to be approximately 10000 fold. In summary, a label-free immunoassay platform combining a preconcentrator which can improve the sensitivity limit by about 10000 fold with highly sensitive SPR sensors is realized. With a simple electrical and optical, low abundance analytes can be preconcentrated and sensed by this label-free platform.
Libros sobre el tema "PLASMONIC NANOGRATINGS"
Lin, C. W., N. F. Chiu y C. C. Chang. Modulation design of plasmonics for diagnostic and drug screening. Editado por A. V. Narlikar y Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.18.
Texto completoActas de conferencias sobre el tema "PLASMONIC NANOGRATINGS"
Shayegannia, Moein, Nastaran Kazemi-Zanjani, Rajiv Prinja, Arthur O. Montazeri, Aliakbar Mohammadzadeh, Siqi Zhu, Ponnambalam R. Selvaganapathy et al. "Multispectral SERS using plasmonic width-graded nanogratings". En Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XVI, editado por Takuo Tanaka y Din Ping Tsai. SPIE, 2018. http://dx.doi.org/10.1117/12.2321517.
Texto completoDixon, Katelyn, Moein Shayegannia, Arthur O. Montazeri, Naomi Matsuura y Nazir P. Kherani. "Rainbow light trapping in ultrathin plasmonic nanogratings". En Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XVII, editado por Takuo Tanaka y Din Ping Tsai. SPIE, 2019. http://dx.doi.org/10.1117/12.2528853.
Texto completoChorsi, Hamid T., Youngkyu Lee, Andrea Alù y John X. J. Zhang. "Plasmonic-enhanced Metallic Nanogratings for Ultrahigh Q-factor Resonances". En Novel Optical Materials and Applications. Washington, D.C.: OSA, 2017. http://dx.doi.org/10.1364/noma.2017.nom2c.5.
Texto completoKrichevsky, D. M., D. O. Ignatyeva, Mehri Hamidi y V. I. Belotelov. "Advanced plasmonic structures based on Au nanogratings on antiferromagnets". En INTERNATIONAL CONFERENCE ON PHYSICS AND CHEMISTRY OF COMBUSTION AND PROCESSES IN EXTREME ENVIRONMENTS (COMPHYSCHEM’20-21) and VI INTERNATIONAL SUMMER SCHOOL “MODERN QUANTUM CHEMISTRY METHODS IN APPLICATIONS”. AIP Publishing, 2020. http://dx.doi.org/10.1063/5.0032086.
Texto completoZeng, Beibei, Yongkang Gao y Filbert J. Bartoli. "Rapid and highly-sensitive detection using Fano resonances in ultrathin plasmonic nanogratings". En CLEO: Science and Innovations. Washington, D.C.: OSA, 2015. http://dx.doi.org/10.1364/cleo_si.2015.sth3m.1.
Texto completoWang, Yuyan, Yu-Yen Huang, Kazunori Hoshino, Ashwini Gopal y Xiaojing Zhang. "Near-field plasmonic enhancement via nanogratings on hollow pyramidal aperture probe tip". En Nanophotonics. IEEE, 2010. http://dx.doi.org/10.1109/omems.2010.5672191.
Texto completoCojocaru, C., S. Mukhopadhyay, L. Rodriguez-Suné, M. A. Vincenti, R. Vilaseca, M. Scalora y J. Trull. "Large Nonlinear Efficiency Enhancement in the Visible and UV Range from Plasmonic Gold Nanogratings". En 2023 23rd International Conference on Transparent Optical Networks (ICTON). IEEE, 2023. http://dx.doi.org/10.1109/icton59386.2023.10207474.
Texto completoMukhopadhyay, S., L. Rodriguez-Suné, C. Cojocaru, M. A. Vincenti, K. Hallman, G. Leo, M. Belchovski, D. De Ceglia, M. Scalora y J. Trull. "Strong Nonlinear Efficiency Enhancement in the Visible and UV Ranges from Plasmonic Gold Nanogratings". En 2023 Conference on Lasers and Electro-Optics Europe & European Quantum Electronics Conference (CLEO/Europe-EQEC). IEEE, 2023. http://dx.doi.org/10.1109/cleo/europe-eqec57999.2023.10231660.
Texto completoNiu, Chao, Tiffany Huang y Jonathan Hu. "Plasmonic nanograting structures for sensor applications". En 2014 Texas Symposium on Wireless and Microwave Circuits and Systems (WMCS). IEEE, 2014. http://dx.doi.org/10.1109/wmcas.2014.7015878.
Texto completoHuang, Tiffany, Xueli Liu y Jonathan Hu. "Plasmonic nanograting structure to detect refractive index". En Frontiers in Optics. Washington, D.C.: OSA, 2013. http://dx.doi.org/10.1364/fio.2013.fth2d.1.
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