01027nam a2200289 i 4500991000510139707536040305s2002 sz a 001 0 eng d3764361352b12627641-39ule_instDip.to Matematicaengengrus512.7221AMS 11B39LC QA241.V61313Vorobiev, Nicolai Nicolaevich482199Chisla Fibonachchi.English54868Fibonacci numbers /Nicolai N. Vorobiev ; translated from the Russian by Mircea MartinBasel :Birkhäuser Verlag,c2002ix, 176 p. :ill. ;24 cmIncludes indexFibonacci numbers.b1262764102-04-1405-03-04991000510139707536LE013 11B VOR11 (2002)12013000145273le013pE31.33-l- 03030.i1324818201-04-04Chisla Fibonachchi54868UNISALENTOle01305-03-04ma -engsz 0104254nam 2200973z- 450 991055728970332120210501(CKB)5400000000041143(oapen)https://directory.doabooks.org/handle/20.500.12854/69440(oapen)doab69440(EXLCZ)99540000000004114320202105d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierOptofluidic Devices and ApplicationsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (148 p.)3-03943-717-8 3-03943-718-6 Optofluidic devices are of high scientific and industrial interest in chemistry, biology, material science, pharmacy, and medicine. In recent years, they have experienced strong development because of impressive achievements in the synergistic combination of photonics and micro/nanofluidics. Sensing and/or lasing platforms showing unprecedented sensitivities in extremely small analyte volumes, and allowing real-time analysis within a lab-on-a-chip approach, have been developed. They are based on the interaction of fluids with evanescent waves induced at the surface of metallic or photonic structures, on the implementation of microcavities to induce optical resonances in the fluid medium, or on other interactions of the microfluidic systems with light. In this context, a large variety of optofluidic devices has emerged, covering topics such as cell manipulation, microfabrication, water purification, energy production, catalytic reactions, microparticle sorting, micro-imaging, or bio-sensing. Moreover, the integration of these optofluidic devices in larger electro-optic platforms represents a highly valuable improvement towards advanced applications, such as those based on surface plasmon resonances that are already on the market. In this Special Issue, we invited the scientific community working in this rapidly evolving field to publish recent research and/or review papers on these optofluidic devices and their applications.History of engineering and technologybicssc3D hydrodynamic focusingaperture ratiobiosensorcellscolored oilcolorimetric methodcolorimetrydissolved oxygendriving waveformdroplet microfluidicselectro-fluidic displayelectrowetting displayfabricationhysteresis characteristicink distributionlab-on-a-chiplaser induced fluorescenceliquid-core waveguidemechanical propertiesmicro-manipulationmicro-thermometrymicro/nanomaterialsmicrofluidicmicroparticlesmicroreactormicroscale channeln/ananofluidicnanohole arraynanoplasmonicocean monitoringoptically-induced dielectrophoresisopto-fluidicsoptoelectrokineticsoptofluidicoptofluidicsorganic dyepaperphoto-stabilityphotocatalysisphotocatalytic water purificationreservoir effectresponse speedrhodamine 6Grhodamine Bsensorseparationsilver nanoprismssingle layersurface plasmon resonancezinc oxideHistory of engineering and technologyYubero Franciscoedt1296149Lahoz FernandoedtYubero FranciscoothLahoz FernandoothBOOK9910557289703321Optofluidic Devices and Applications3023810UNINA