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Gas Flows in Microsystems



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Autore: Baldas Lucien Visualizza persona
Titolo: Gas Flows in Microsystems Visualizza cluster
Pubblicazione: MDPI - Multidisciplinary Digital Publishing Institute, 2019
Descrizione fisica: 1 electronic resource (220 p.)
Soggetto non controllato: preconcentrator
UV absorption
bearing characteristics
ultraviolet light-emitting diode (UV LED)
resonant micro-electromechanical-systems (MEMS)
heat sinks
measurement and control
flow choking
mixing length
gas flows in micro scale
BTEX
kinetic theory
PID detector
ethylbenzene and xylene (BTEX)
computational fluid dynamics (CFD)
OpenFOAM
direct simulation Monte Carlo (DSMC)
thermally induced flow
vacuum micropump
miniaturization
gaseous rarefaction effects
modelling
volatile organic compound (VOC) detection
supersonic microjets
slip flow
Nano-Electro-Mechanical Systems (NEMS)
micro-mirrors
micro-scale flows
microfabrication
Knudsen pump
microfluidic
microfluidics
hollow core waveguides
capillary tubes
gas mixing
advanced measurement technologies
DSMC
Micro-Electro-Mechanical Systems (MEMS)
microchannels
miniaturized gas chromatograph
Pitot tube
multi-stage micromixer
analytical solution
pressure drop
micro-mixer
thermal transpiration
photoionization detector
FE analysis
gas mixtures
spectrophotometry
Knudsen layer
pulsed flow
Fanno flow
integrated micro sensors
binary gas mixing
modified Reynolds equation
rarefied gas flow
rarefied gas flows
backward facing step
modular micromixer
fractal surface topography
underexpansion
electronic cooling
splitter
compressibility
photolithography
Benzene
out-of-plane comb actuation
gas sensors
aerodynamic effect
fluid damping
toluene
control mixture composition
Persona (resp. second.): ColinStéphane
Sommario/riassunto: The last two decades have witnessed a rapid development of microelectromechanical systems (MEMS) involving gas microflows in various technical fields. Gas microflows can, for example, be observed in microheat exchangers designed for chemical applications or for cooling of electronic components, in fluidic microactuators developed for active flow control purposes, in micronozzles used for the micropropulsion of nano and picosats, in microgas chromatographs, analyzers or separators, in vacuum generators and in Knudsen micropumps, as well as in some organs-on-a-chip, such as artificial lungs. These flows are rarefied due to the small MEMS dimensions, and the rarefaction can be increased by low-pressure conditions. The flows relate to the slip flow, transition or free molecular regimes and can involve monatomic or polyatomic gases and gas mixtures. Hydrodynamics and heat and mass transfer are strongly impacted by rarefaction effects, and temperature-driven microflows offer new opportunities for designing original MEMS for gas pumping or separation. Accordingly, this Special Issue seeks to showcase research papers, short communications, and review articles that focus on novel theoretical and numerical models or data, as well as on new experimental results and technics, for improving knowledge on heat and mass transfer in gas microflows. Papers dealing with the development of original gas MEMS are also welcome.
Titolo autorizzato: Gas Flows in Microsystems  Visualizza cluster
ISBN: 3-03921-543-4
Formato: Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione: Inglese
Record Nr.: 9910367750003321
Lo trovi qui: Univ. Federico II
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