Optofluidics, Sensors and Actuators in Microstructured Optical Fibers - 1st Edition - ISBN: 9781782423294, 9781782423478

Optofluidics, Sensors and Actuators in Microstructured Optical Fibers

1st Edition

Editors: Stavros Pissadakis Stefano Selleri
eBook ISBN: 9781782423478
Hardcover ISBN: 9781782423294
Imprint: Woodhead Publishing
Published Date: 20th May 2015
Page Count: 312
Tax/VAT will be calculated at check-out Price includes VAT (GST)
20% off
20% off
20% off
190.00
152.00
160.00
128.00
265.00
212.00
Unavailable
Price includes VAT (GST)
DRM-Free

Easy - Download and start reading immediately. There’s no activation process to access eBooks; all eBooks are fully searchable, and enabled for copying, pasting, and printing.

Flexible - Read on multiple operating systems and devices. Easily read eBooks on smart phones, computers, or any eBook readers, including Kindle.

Open - Buy once, receive and download all available eBook formats, including PDF, EPUB, and Mobi (for Kindle).

Institutional Access

Secure Checkout

Personal information is secured with SSL technology.

Free Shipping

Free global shipping
No minimum order.

Description

Combining the positive characteristics of microfluidics and optics, microstructured optical fibres (MOFs) have revolutionized the field of optoelectronics. Tailored guiding, diffractive structures and photonic band-gap effects are used to produce fibres with highly specialised, complex structures, facilitating the development of novel kinds of optical fibre sensors and actuators.

Part One outlines the key materials and fabrication techniques used for microstructured optical fibres. Microfluidics and heat flows, MOF-based metamaterials, novel and liquid crystal infiltrated photonic crystal fibre (PCF) designs, MOFs filled with carbon nanotubes and melting of functional inorganic glasses inside PCFs are all reviewed. Part Two then goes on to investigate sensing and optofluidic applications, with the use of MOFs in structural sensing, sensing units and mechanical sensing explored in detail. PCF’s for switching applications are then discussed before the book concludes by reviewing MOFs for specific nucleic acid detection and resonant bio- and chemical sensing.

Key Features

  • Provides users with the necessary knowledge to successfully design and implement microstructured optical fibres for a broad range of uses
  • Outlines techniques for developing both traditional and novel types of optical fibre
  • Highlights the adaptability of microstructured optical fibres achieved via the use of optofluidics, sensors and actuators, by presenting a diverse selection of applications

Readership

Postgraduate students and academic researchers in electronics, optics, photonics, sensors, physics, material science and engineering, as well as R&D managers in such industrial sectors as industrial process monitoring, structural health monitoring and environmental monitoring

Table of Contents

  • Related titles
  • List of contributors
  • Woodhead Publishing Series in Electronic and Optical Materials
  • Preface
  • Part One. Materials and fabrication of microstructured optical fibres
    • 1. Microfluidics flow and heat transfer in microstructured fibers of circular and elliptical geometry
      • 1.1. Introduction
      • 1.2. Governing equations of flows along a microchannel
      • 1.3. Numerical results
      • 1.4. Conclusions
    • 2. Drawn metamaterials
      • 2.1. Introduction
      • 2.2. Fibre-based metamaterials
      • 2.3. Drawn wire array metamaterials
      • 2.4. Drawn magnetic metamaterials
      • 2.5. Applications
      • 2.6. Future directions—challenges and opportunities
      • 2.7. Conclusions
    • 3. Liquid crystal-infiltrated photonic crystal fibres for switching applications
      • 3.1. Introduction
      • 3.2. LCs in cylindrical capillaries
      • 3.3. Light guidance in LC-infiltrated PCFs
      • 3.4. Switching components based on LC-infiltrated PCFs
      • 3.5. Concluding remarks
    • 4. Microstructured optical fiber filled with carbon nanotubes
      • 4.1. Introduction
      • 4.2. Carbon nanotubes as advanced materials for environmental monitoring
      • 4.3. Carbon nanotubes integration techniques with optical fibers
      • 4.4. Sensing probes fabrication
      • 4.5. Experimental results
      • 4.6. Conclusions
    • 5. Molten glass-infiltrated photonic crystal fibers
      • 5.1. Glassy materials: and why glass-infiltrated photonic crystal fibers (PCFs)?
      • 5.2. Glass-infiltrated PCFs: state of the art and fabrication techniques
      • 5.3. PBG guidance characteristics of composite all-glass PCFs
      • 5.4. Prospects and future directions
      • 5.5. Conclusions and final remarks
  • Part Two. Sensing and optofluidic applications
    • 6. Microstructured optical fibre-based sensors for structural health monitoring applications
      • 6.1. Introduction to structural health monitoring applications and fibre Bragg grating sensors
      • 6.2. Microstructured optical fibres for temperature-insensitive pressure and transverse strain sensing
      • 6.3. Structural health monitoring-related applications of the butterfly microstructured optical fibres
      • 6.4. Conclusion and trends
    • 7. Liquid crystals infiltrated photonic crystal fibers (PCFs) for electromagnetic field sensing
      • 7.1. Introduction—state of the art: photonic liquid crystal fibers for electromagnetic field sensing
      • 7.2. LCs infiltrated microstructured optical fibers
      • 7.3. Electric field-induced effects
      • 7.4. Optical field-induced effects
      • 7.5. Conclusions and research directions
    • 8. Polymer micro and microstructured fiber Bragg gratings: recent advancements and applications
      • 8.1. Introduction
      • 8.2. Polymer optical fibers
      • 8.3. Polymer fiber Bragg gratings
      • 8.4. Applications of polymer fiber Bragg grating sensors
      • 8.5. Conclusions
    • 9. Functionalized microstructured optical fibers for specific nucleic acid detection
      • 9.1. Introduction
      • 9.2. Functionalization and hybridization process
      • 9.3. Label-free DNA biosensors based on PNA-functionalized microstructured optical fiber gratings
      • 9.4. Detection of unamplified genomic DNA using a large mode area fiber
      • 9.5. Conclusion
    • 10. Photonic bandgap fibers—a roadway to all-fiber refractometer systems for monitoring of liquid analytes
      • 10.1. Introduction
      • 10.2. Resonant sensing of liquid-core fiber sensors—a theoretical foundation
      • 10.3. Capillary fiber sensors
      • 10.4. Hollow-core photonic crystal fiber sensors
      • 10.5. Liquid-core Bragg fiber sensors
      • 10.6. Solid-core photonic bandgap Bragg fiber spectrometers
      • 10.7. Hollow-core Bragg fiber sensor interrogated with all-fiber spectrometer—an all-fiber spectroscopic system
      • 10.8. Examples of practical applications of the liquid-core Bragg fiber sensors
  • Index

Details

No. of pages:
312
Language:
English
Copyright:
© Woodhead Publishing 2015
Published:
Imprint:
Woodhead Publishing
eBook ISBN:
9781782423478
Hardcover ISBN:
9781782423294

About the Editor

Stavros Pissadakis

Affiliations and Expertise

Foundation for Research and Technology - Hellas (FORTH), Greece

Stefano Selleri

Affiliations and Expertise

University of Parma, Italy