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![Photonic crystal waveguide applications of chemistry: >> http://prm.cloudz.pw/download?file=photonic+crystal+waveguide+applications+of+chemistry << (Download)
Photonic crystal waveguide applications of chemistry: >> http://prm.cloudz.pw/read?file=photonic+crystal+waveguide+applications+of+chemistry << (Read Online)
Bio-Chemical Sensor Based on Photonic Crystal Waveguide for Estimation of Sulphuric Acid Concentration. Balveer Painam, Pradeep Kumar Teotia, R. S. Kaler, and Dr. Mukesh kumar. Author Information
17 Oct 2016 Photonic crystal (PhC) waveguides are used for a wide range of applications with diverse performance metrics. A waveguide optimised for one application may not be suitable for others and no one-size-fits-all solution exists. Therefore each application requires a specialised waveguide design,
Optimizing photonic crystal waveguides for on-chip spectroscopic applications Through numerical simulation, we show that a properly-optimized photonic crystal waveguide could form the basis of a spectrometer with a spectral resolution of 0.04 nm over a 12.5 nm bandwidth near 1550 nm and with a footprint six times
Photonic crystal waveguide (PCW) sensors represents an efficient and accurate solution for chemical and biochemical sensing. Here, we propose a design of photonic crystal waveguide sensor for chemical sens- ing applications. The proposed PCW sensor is patterned on 10 ? 10 m silicon on insulator (SOI) wafer.
27 Jul 2016 Abstract The rapid progress in chemical and biochemical applications with optical interfaces has motivated an ever- increasing demand for highly sensitive, accurate, and dispos- able photonic components. We propose a design of biochem- ical sensor to identify the chemical components acid concen-.
Photonic crystal waveguide (PCW) based device has been used in many applications in recent years due to its unique slow light effect. In this work, the application of PCW on sensing is presented. First, we present a PCW structure based Infrared (IR) spectroscopy combining with slot structure which has a large electric field
Crystal waveguides and cavities, where light is confined in extremely small air volumes, for slow light and chemical sensing applications. Keywords- Photonic Crystal waveguides; Photonic crystal microcavities; slow light; chemical sensing. I. INTRODUCTION. Since their recent introduction Slotted Photonic Crystal (SPhC).
24 Aug 2016 Quality factor, full width at half maximum (FWHM), free spectral range (FSR), detection limit (DL), and sensitivity are the most important parameters in sensing applications which are introduced in Section 3. Finally, the last section describes some structures of photonic crystal chemical/biochemical sensors.
M.A. Fakhri, Y. Al-Douri, U. Hashim, E.T. SalimAnnealing Temperature Effects on Morphological and Optical Studies of Nano and Micro Photonics Lithium Niobate using for Optical Waveguide Applications. Australian Journal of Basic and Applied Sciences, 9 (2015), pp. 128-133. [2]. E. Marenna, C. Aruta, E. Fanelli, M. Barra,](http://cdn08.dayviews.com/501/_u4/_u1/_u3/_u1/_u4/_u3/u4131432/60622_1515621480/Photonic_crystal_waveguide_applications_of_chemistry_http_prm_cloudz_pw_download_file_photonic.jpg)
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Photonic crystal waveguide applications of chemistry: >> http://prm.cloudz.pw/download?file=photonic+crystal+waveguide+applications+of+chemistry << (Download)
Photonic crystal waveguide applications of chemistry: >> http://prm.cloudz.pw/read?file=photonic+crystal+waveguide+applications+of+chemistry << (Read Online)
Bio-Chemical Sensor Based on Photonic Crystal Waveguide for Estimation of Sulphuric Acid Concentration. Balveer Painam, Pradeep Kumar Teotia, R. S. Kaler, and Dr. Mukesh kumar. Author Information
17 Oct 2016 Photonic crystal (PhC) waveguides are used for a wide range of applications with diverse performance metrics. A waveguide optimised for one application may not be suitable for others and no one-size-fits-all solution exists. Therefore each application requires a specialised waveguide design,
Optimizing photonic crystal waveguides for on-chip spectroscopic applications Through numerical simulation, we show that a properly-optimized photonic crystal waveguide could form the basis of a spectrometer with a spectral resolution of 0.04 nm over a 12.5 nm bandwidth near 1550 nm and with a footprint six times
Photonic crystal waveguide (PCW) sensors represents an efficient and accurate solution for chemical and biochemical sensing. Here, we propose a design of photonic crystal waveguide sensor for chemical sens- ing applications. The proposed PCW sensor is patterned on 10 ? 10 m silicon on insulator (SOI) wafer.
27 Jul 2016 Abstract The rapid progress in chemical and biochemical applications with optical interfaces has motivated an ever- increasing demand for highly sensitive, accurate, and dispos- able photonic components. We propose a design of biochem- ical sensor to identify the chemical components acid concen-.
Photonic crystal waveguide (PCW) based device has been used in many applications in recent years due to its unique slow light effect. In this work, the application of PCW on sensing is presented. First, we present a PCW structure based Infrared (IR) spectroscopy combining with slot structure which has a large electric field
Crystal waveguides and cavities, where light is confined in extremely small air volumes, for slow light and chemical sensing applications. Keywords- Photonic Crystal waveguides; Photonic crystal microcavities; slow light; chemical sensing. I. INTRODUCTION. Since their recent introduction Slotted Photonic Crystal (SPhC).
24 Aug 2016 Quality factor, full width at half maximum (FWHM), free spectral range (FSR), detection limit (DL), and sensitivity are the most important parameters in sensing applications which are introduced in Section 3. Finally, the last section describes some structures of photonic crystal chemical/biochemical sensors.
M.A. Fakhri, Y. Al-Douri, U. Hashim, E.T. SalimAnnealing Temperature Effects on Morphological and Optical Studies of Nano and Micro Photonics Lithium Niobate using for Optical Waveguide Applications. Australian Journal of Basic and Applied Sciences, 9 (2015), pp. 128-133. [2]. E. Marenna, C. Aruta, E. Fanelli, M. Barra,
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