00786nam0-2200289---450 99000928612040332120171024132445.0000928612FED01000928612(Aleph)000928612FED0100092861220101125d1900----km-y0itay50------baitaITa-------001yyCompendio di ostetriciaG. De AngelisNapoliGabriele Regina1900368 p.ill.18 cmOstetriciaDe Angelis,Giovanni<medico>288183ITUNINARICAUNIMARCBK99000928612040332190 CCH GINECOLOGIA 36795FMEBCFMEBCCompendio di ostetricia769741UNINA05540nam 2200673 450 991078827920332120200520144314.0(CKB)2670000000617488(EBL)2055761(SSID)ssj0001539503(PQKBManifestationID)11828905(PQKBTitleCode)TC0001539503(PQKBWorkID)11531751(PQKB)11273159(Au-PeEL)EBL2055761(CaPaEBR)ebr11056844(CaONFJC)MIL787625(OCoLC)910446898(CaSebORM)9781782423478(MiAaPQ)EBC2055761(EXLCZ)99267000000061748820150605h20152015 uy 0engur|n|---|||||txtccrOptofluidics, sensors and actuators in microstructured optical fibres /edited by Stavros Pissadakis and Stefano Selleri1st editionCambridge, England :Woodhead Publishing,2015.©20151 online resource (313 p.)Woodhead Publishing Series in Electronic and Optical Materials ;Number 79Description based upon print version of record.1-78242-347-8 1-78242-329-X Includes bibliographical references and index.Front Cover; Related titles; Optofluidics, Sensors and Actuators in Microstructured Optical FibersWoodhead Publishing Series in Electronic and Optical M ...; Copyright; Contents; List of contributors; Woodhead Publishing Series in Electronic and Optical Materials; Preface; Part 1 - 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; Acknowledgments; References2 - Drawn metamaterials2.1 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; References; 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; Acknowledgements; References; 4 - Microstructured optical fiber filled with carbon nanotubes4.1 Introduction4.2 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; References; 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; AcknowledgmentsReferencesPart 2 - 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; Acknowledgements; References7 - Liquid crystals infiltrated photonic crystal fibers (PCFs) for electromagnetic field sensing7.1 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; Acknowledgments; References; 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 gratings8.4 Applications of polymer fiber Bragg grating sensors 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 fWoodhead Publishing series in electronic and optical materials ;Number 79.Fiber opticsFiber opticsReliabilityFiber optics.Fiber opticsReliability.621.3692Pissadakis StavrosSelleri StefanoMiAaPQMiAaPQMiAaPQBOOK9910788279203321Optofluidics, sensors and actuators in microstructured optical fibres3711761UNINA01228nam0 22002891i 450 UON0047901320231205105240.37720170707f1974 |0itac50 baitaIT|||| 1||||Lineamenti di grammatica dell'antico alto tedescoGiorgio Dolfini2a ed.riveduta e ampliataMilanoMursiac1974103 p.24 cm001UON004040922001 Collana di Filologia GermanicaCarlo Alberto Mastrellidir.]2LINGUA TEDESCA ANTICAGrammaticaUONC040629FIITMilanoUONL000005437.01Varianti storiche e geografiche, varianti non geografiche moderne. Antico alto tedesco, fino al 110021DOLFINIGiorgioUONV170893192640MursiaUONV246158650ITSOL20241115RICASIBA - SISTEMA BIBLIOTECARIO DI ATENEOUONSIUON00479013SIBA - SISTEMA BIBLIOTECARIO DI ATENEOSI Fil.G IV 150 SI 22849 5 150 Lineamenti di grammatica dell'antico alto tedesco131923UNIOR