Optofluidics, Sensors and Actuators in Microstructured Optical Fibers

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.

Part One: Materials and Fabrication of Microstructured Optical Fibres1 Microfluidics and heat flows in microstructured optical fibres 2 Microstructured optical fibre (MOF)-based metamaterials 3 Liquid crystal infiltrated photonic crystal fibres (PCFs) for switching applications 4 Microstructured optical fiber filled with carbon nanotubes 5 Molten glass infiltrated photonic crystal fibresPart Two: Sensing and Optofluidic Applications6 Photonic crystal fibres (PCFs) sensing units for structural health monitoring 7 Liquid crystal infiltrated photonic crystal fibres (PCFs) for electromagnetic field sensing 8 Structural sensing using photonic crystal fibres (PCFs) 9 Functionalized microstructured optical fibers for specific nucleic acid detection10 Microstructured and photonic bandgap fibers for applications in the resonant bio- and chemical sensors