Tracer and Timescale Methods for Passive and Reactive Transport in Fluid Flows

Tracer and Timescale Methods for Passive and Reactive Transport in Fluid Flows

Geophysical, environmental, and urban fluid flows (i.e., flows developing in oceans, seas, estuaries, rivers, aquifers, reservoirs, etc.) exhibit a wide range of reactive and transport processes. Therefore, identifying key phenomena, understanding their relative importance, and establishing causal r...

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Bibliographic Details
HerausgeberIn:
Koszalka, Inga Monika
Lucas, Lisa V.
Sonstige:
Deleersnijder, Eric
Koszalka, Inga Monika
Lucas, Lisa V.
Year of Publication:2022
Language:English
Physical Description:1 electronic resource (364 p.)
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520 |a Geophysical, environmental, and urban fluid flows (i.e., flows developing in oceans, seas, estuaries, rivers, aquifers, reservoirs, etc.) exhibit a wide range of reactive and transport processes. Therefore, identifying key phenomena, understanding their relative importance, and establishing causal relationships between them is no trivial task. Analysis of primitive variables (e.g., velocity components, pressure, temperature, concentration) is not always conducive to the most fruitful interpretations. Examining auxiliary variables introduced for diagnostic purposes is an option worth considering. In this respect, tracer and timescale methods are proving to be very effective. Such methods can help address questions such as, "where does a fluid-born dissolved or particulate substance come from and where will it go?" or, "how fast are the transport and reaction phenomena controlling the appearance and disappearance such substances?" These issues have been dealt with since the 19th century, essentially by means of ad hoc approaches. However, over the past three decades, methods resting on solid theoretical foundations have been developed, which permit the evaluation of tracer concentrations and diagnostic timescales (age, residence/exposure time, etc.) across space and time and using numerical models and field data. This book comprises research and review articles, introducing state-of-the-art diagnostic theories and their applications to domains ranging from shallow human-made reservoirs to lakes, river networks, marine domains, and subsurface flows 
546 |a English 
650 7 |a Research & information: general  |2 bicssc 
650 7 |a Biology, life sciences  |2 bicssc 
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653 |a density current 
653 |a water level regulation 
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653 |a transport timescales 
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653 |a macro-tidal 
653 |a wind influence 
653 |a floating structures 
653 |a San Francisco Estuary 
653 |a Sacramento-San Joaquin Delta 
653 |a water age 
653 |a transport time scales 
653 |a hydrodynamic model 
653 |a tidal hydrodynamics 
653 |a stable isotopes 
653 |a reactive tracers 
653 |a tailor-made tracer design 
653 |a hydrogeological tracer test 
653 |a kinetics 
653 |a partitioning 
653 |a Mahakam Delta 
653 |a age 
653 |a exposure time 
653 |a return coefficient 
653 |a CART 
653 |a source water fingerprinting 
653 |a floodplain 
653 |a turbulence 
653 |a ADCP measurement 
653 |a wave bias 
653 |a Reynolds stress 
653 |a transport process 
653 |a passive tracers 
653 |a terrestrial dissolved substances 
653 |a Pearl River Estuary 
653 |a shallow lake 
653 |a meteorological influence 
653 |a sub-basins 
653 |a Delft3D 
653 |a partial differential equations 
653 |a boundary conditions 
653 |a geophysical and environmental fluid flows 
653 |a reactive transport 
653 |a interpretation methods 
653 |a diagnostic timescales 
653 |a age distribution function 
653 |a radionuclide 
653 |a tracer 
653 |a data collection 
653 |a antimony 125 (125Sb) 
653 |a tritium (3H) 
653 |a dispersion 
653 |a modeling 
653 |a English Channel 
653 |a North Sea 
653 |a Biscay Bay 
653 |a timescale 
653 |a transport 
653 |a hydrodynamic 
653 |a ecological 
653 |a biogeochemical 
653 |a coastal 
653 |a estuary 
653 |a flushing time 
653 |a shallow reservoir 
653 |a numerical modeling 
653 |a Lagrangian transport modelling 
653 |a coupled wave-ocean models 
653 |a ocean drifters 
653 |a wave-induced processes 
653 |a model skills 
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700 1 |a Lucas, Lisa V.  |4 edt 
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