DNS of a spatially developing turbulent boundary layer with passive scalar transport

International Journal of Heat and Fluid Flow

Volumn 30, Issue 5, 2009, Pages 916-929

  Li, Qiang ^a   Schlatter, Philipp ^a   Brandt, Luca ^a   Henningson, Dan S ^a  

^a ROYAL INSTITUTE OF TECHNOLOGY   (Sweden)

Author keywords

Direct numerical simulation (DNS); Passive scalar; Prandtl number; Turbulent boundary layer

Indexed keywords

DIRECT NUMERICAL SIMULATION (DNS); FLAT PLATE; FREE-STREAM VELOCITY; INTERMITTENCY; ISOFLUX WALL BOUNDARY CONDITIONS; JOINT PROBABILITY DENSITY FUNCTION; MOLECULAR PRANDTL NUMBER; MOMENTUM THICKNESS; NEAR-WALL STREAKS; NUMERICAL SIMULATION; PASSIVE SCALAR; PASSIVE SCALARS; PROBABILITY DENSITY FUNCTION (PDF); RESEARCH COMMUNITIES; SCALAR FIELDS; SCALAR TRANSPORT EQUATION; SCALINGS; SIMULATION DATA; SPATIALLY DEVELOPING TURBULENT BOUNDARY LAYERS; SPECTRAL METHODS; TURBULENCE STATISTICS; TURBULENT BOUNDARY LAYER; TWO-POINT CORRELATION; WALL BOUNDARY CONDITION; ZERO PRESSURE GRADIENT;

ATMOSPHERIC THERMODYNAMICS; BOUNDARY CONDITIONS; BOUNDARY LAYER FLOW; BOUNDARY LAYERS; DIRECT NUMERICAL SIMULATION; INTERNET PROTOCOLS; NAVIER STOKES EQUATIONS; PRANDTL NUMBER; PRESSURE GRADIENT; REGRESSION ANALYSIS; REYNOLDS NUMBER; SPECTROSCOPY; TURBULENCE; TURBULENT FLOW;

PROBABILITY DENSITY FUNCTION;

EID: 70249119222     PISSN: 0142727X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijheatfluidflow.2009.06.007     Document Type: Article

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