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In my career I’ve found that ‘‘thinking outside the box’’ works better if I know what’s ‘‘inside the box.’’ Dave Grusin, composer and jazz musician Different people think in different time frames: scientists think in decades, engineers think in years, and investors think in quarters. Stan Williams, Director of Quantum Science Research, Hewlett Packard Laboratories Everything can be made smaller, never mind physics; Everything can be made more ef?cient, never mind thermodynamics; Everything will be more expensive, never mind common sense. Tomas Hirschfeld, pioneer of industrial spectroscopy…mehr
In my career I’ve found that ‘‘thinking outside the box’’ works better if I know what’s ‘‘inside the box.’’ Dave Grusin, composer and jazz musician Different people think in different time frames: scientists think in decades, engineers think in years, and investors think in quarters. Stan Williams, Director of Quantum Science Research, Hewlett Packard Laboratories Everything can be made smaller, never mind physics; Everything can be made more ef?cient, never mind thermodynamics; Everything will be more expensive, never mind common sense. Tomas Hirschfeld, pioneer of industrial spectroscopy Integrated Analytical Systems Series Editor: Dr. Radislav A. Potyrailo, GE Global Research, Niskayuna, NY The book series Integrated Analytical Systems offers the most recent advances in all key aspects of development and applications of modern instrumentation for che- cal and biological analysis. The key development aspects include (i) innovations in sample introduction through micro- and nano?uidic designs, (ii) new types and methods of fabrication of physical transducers and ion detectors, (iii) materials for sensors that became available due to the breakthroughs in biology, combinatorial materials science, and nanotechnology, and (iv) innovative data processing and mining methodologies that provide dramatically reduced rates of false alarms.
General Introduction.- General Introduction.- Photonic Structures for Chemical Vapor Sensing.- Microresonator Sensors Made in Polymers with Functional Chromophore Dopants.- Modal Transition in Nano-Coated Long Period Fiber Gratings: Principle and Applications to Chemical Sensing.- New Approach for Selective Vapor Sensing Using Structurally Colored Self-Assembled Films.- Methods of Cavity-Enhanced Laser Absorption Spectroscopy Using Microresonator Whispering-Gallery Modes.- Rapid Chemical Vapor Detection Using Optofluidic Ring Resonators.- Miniaturized Optical Fiber Inline Interferometers for Chemical Sensing.- Photonic Structures for Biochemical Sensing.- Label-Free Biochemical Sensors Based on Optical Microresonators.- Silicon Photonic Wire Waveguide Sensors.- A Fast and Sensitive Integrated Young Interferometer Biosensor.- The BioCD: High-Speed Interferometric Optical Biosensor.- Ultra-Sensitive Biochemical Optical Detection Using Distributed Feedback Nanolasers.- Optical Micro/Nanofibers for Sensing Applications.- Label-Free Biosensing with the Optofluidic Ring Resonator.- Deep-Probe Optical Waveguides for Chemical and Biosensors.- Microfluidics Enabled Photonic Sensing Systems.- Optically Resonant Nanophotonic Devices for Label-Free Biomolecular Detection.- Droplet Based Cavities and Lasers.- Single Molecule Analysis with Planar Optofluidics.- Optofluidic Ring Resonator Dye Microlasers.- Erratum To.
General Introduction.- Section I: Photonic structures for chemical vapor sensing.- Micro-resonator Sensors Made in Polymers with Functional Chromophore Dopants.- Modal Transition in Nano-Coated Long Period Fiber Gratings: Principle and Applications to Chemical Sensing.- New Approach for Selective Vapor Sensing Using Structurally Colored Self-Assembled Films.- Methods of Cavity-Enhanced Laser Absorption Spectroscopy Using Microresonator Whispering-Gallery Modes.- Rapid chemical vapor detection using optofluidic ring resonators.- Miniaturized Optical Fiber Inline Interferometers for Chemical Sensing.- Section II. Photonic structures for biochemical sensing.- Label-free Bio-Chemical Sensors Based on Optical Micro-Resonators.- Silicon Photonic Wire Waveguide Sensors.- A Fast and Sensitive Integrated Young Interferometer Biosensor.- The BioCD: High-Speed Interferometric Optical Biosensor.- Ultra-Sensitive biochemical optical detection using distributed feedback nano-lasers.- Optical micro/nanofibers for sensing applications.- Label-Free Biosensing with the Optofluidic Ring Resonator.- Deep-Probe Optical Waveguides for Chemical and Biosensors.- Section III. Microfluidics enabled photonic sensing systems.- Optically Resonant Nanophotonic Devices for Label-Free Biomolecular Detection.- Droplet based cavities and lasers.- Single molecule analysis with planar optofluidics.- Optofluidic ring resonator dye microlasers
General Introduction.- General Introduction.- Photonic Structures for Chemical Vapor Sensing.- Microresonator Sensors Made in Polymers with Functional Chromophore Dopants.- Modal Transition in Nano-Coated Long Period Fiber Gratings: Principle and Applications to Chemical Sensing.- New Approach for Selective Vapor Sensing Using Structurally Colored Self-Assembled Films.- Methods of Cavity-Enhanced Laser Absorption Spectroscopy Using Microresonator Whispering-Gallery Modes.- Rapid Chemical Vapor Detection Using Optofluidic Ring Resonators.- Miniaturized Optical Fiber Inline Interferometers for Chemical Sensing.- Photonic Structures for Biochemical Sensing.- Label-Free Biochemical Sensors Based on Optical Microresonators.- Silicon Photonic Wire Waveguide Sensors.- A Fast and Sensitive Integrated Young Interferometer Biosensor.- The BioCD: High-Speed Interferometric Optical Biosensor.- Ultra-Sensitive Biochemical Optical Detection Using Distributed Feedback Nanolasers.- Optical Micro/Nanofibers for Sensing Applications.- Label-Free Biosensing with the Optofluidic Ring Resonator.- Deep-Probe Optical Waveguides for Chemical and Biosensors.- Microfluidics Enabled Photonic Sensing Systems.- Optically Resonant Nanophotonic Devices for Label-Free Biomolecular Detection.- Droplet Based Cavities and Lasers.- Single Molecule Analysis with Planar Optofluidics.- Optofluidic Ring Resonator Dye Microlasers.- Erratum To.
General Introduction.- Section I: Photonic structures for chemical vapor sensing.- Micro-resonator Sensors Made in Polymers with Functional Chromophore Dopants.- Modal Transition in Nano-Coated Long Period Fiber Gratings: Principle and Applications to Chemical Sensing.- New Approach for Selective Vapor Sensing Using Structurally Colored Self-Assembled Films.- Methods of Cavity-Enhanced Laser Absorption Spectroscopy Using Microresonator Whispering-Gallery Modes.- Rapid chemical vapor detection using optofluidic ring resonators.- Miniaturized Optical Fiber Inline Interferometers for Chemical Sensing.- Section II. Photonic structures for biochemical sensing.- Label-free Bio-Chemical Sensors Based on Optical Micro-Resonators.- Silicon Photonic Wire Waveguide Sensors.- A Fast and Sensitive Integrated Young Interferometer Biosensor.- The BioCD: High-Speed Interferometric Optical Biosensor.- Ultra-Sensitive biochemical optical detection using distributed feedback nano-lasers.- Optical micro/nanofibers for sensing applications.- Label-Free Biosensing with the Optofluidic Ring Resonator.- Deep-Probe Optical Waveguides for Chemical and Biosensors.- Section III. Microfluidics enabled photonic sensing systems.- Optically Resonant Nanophotonic Devices for Label-Free Biomolecular Detection.- Droplet based cavities and lasers.- Single molecule analysis with planar optofluidics.- Optofluidic ring resonator dye microlasers
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