LEADER 04381nam  2201261z- 450 
001 9910346858803321
005 20231214133446.0
035   $a(CKB)4920000000095079
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/61405
035   $a(EXLCZ)994920000000095079
100   $a20202102d2019      |y             0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aTurbulence in River and Maritime Hydraulics
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2019
215   $a1 electronic resource (296 p.)
311   $a3-03897-594-X 
330   $aUnderstanding of the role of turbulence in controlling transport processes is of paramount importance for the preservation and protection of aquatic ecosystems, the minimization of the deleterious consequences of anthropogenic activity, and the successful sustainable development of river and maritime areas. In this context, the present Special Issue collects 15 papers which provide a representation of the present understanding of turbulent processes and their effects in river and maritime environments. The presented collection of papers is not exhaustive, but it highlights the key priority areas and knowledge gaps in this field of research. The published papers present the state-of-the-art knowledge of complex environmental flows which are useful for researchers and practitioners. The paper contents are an overview of some recent topics of research and an exposure of the current and future challenges associated with these topics.
610   $ainclined negatively buoyant jets
610   $aflow mixing
610   $aKelvin?Helmholtz
610   $aflow-through system
610   $amixing
610   $aregular waves
610   $avegetation patch
610   $aturbulence invariants
610   $ajunction angle
610   $agravel-bed rivers
610   $aspatial analysis
610   $aspectral model
610   $acoastal lagoon
610   $aroughness
610   $aMIKE 21 FM (HD)
610   $abillow
610   $adissipation
610   $ariver mouth
610   $awaves
610   $aadvection
610   $awave?current interaction
610   $aplunging breaking waves
610   $aturbulence
610   $aflow deflection zone
610   $asmoothed particle hydrodynamics models
610   $anumerical modelling
610   $aphysical modelling
610   $asurface waves
610   $alobe
610   $adilution
610   $anumerical model
610   $achannel confluences
610   $aprediction
610   $ameanders
610   $aCFD
610   $abedrock canyon
610   $aMIKE 3 FM (HD &
610   $aSVF
610   $adiffusion
610   $adense jet
610   $asub-grid turbulence
610   $aflow separation zone
610   $abreaking waves
610   $a<i>Spartina maritima</i>
610   $ajets
610   $amaritime areas
610   $aflow retardation zone
610   $aseabed friction
610   $asea discharges
610   $asecondary motion
610   $aADCP
610   $acleft
610   $asubmerged ratio
610   $alaboratory experiments
610   $awake region
610   $aeddy viscosity
610   $abottom friction
610   $acasting technique
610   $aturbulent jet
610   $atidal inlets
610   $arivers
610   $anonlinear shallow water equations
610   $avorticity
610   $ahydrodynamic model
610   $aflow resistance
610   $aPANORMUS
610   $aspectral dissipation
610   $aTR)
610   $amacrovortices
610   $aturbulent processes
610   $avelocity
610   $atrajectory
610   $aflexible vegetation
610   $aenergy dissipation
610   $agravity current
610   $abed shear stress
610   $acurrent flow
610   $adrag coefficient
610   $aresidence time
610   $awave attenuation
700   $aDavies$b Peter A$4auth$0287468
702   $aTermini$b Donatella$4auth
702   $aMossa$b Michele$4auth
906   $aBOOK
912   $a9910346858803321
996   $aTurbulence in River and Maritime Hydraulics$93011637
997   $aUNINA