Simulation of natural convection under high magnetic field by means of the thermal lattice Boltzmann method

Chinese Physics B

Volumn 18, Issue 10, 2009, Pages 4083-4093

  Zhong, Cheng Wen ^a   Xie, Jian Fei ^a   Zhuo, Cong Shan ^a   Xiong, Sheng Wei ^a   Yin, Da Chuan ^a  

^a NORTHWESTERN POLYTECHNICAL UNIVERSITY   (China)

Author keywords

Lorentz force; Magnetization force; Natural convection; Thermal lattice Boltzmann method

Indexed keywords

AQUEOUS SOLUTIONS; BENCHMARK DATA; BODY FORCES; BOUNCE-BACK BOUNDARY CONDITION; CAVITY LOCATION; CONDUCTING FLUID; DIAMAGNETIC FLUIDS; DIFFERENT DISTRIBUTIONS; EQUILIBRIUM SOLUTIONS; EXTRAPOLATION SCHEMES; HIGH MAGNETIC FIELDS; IMPROVED METHODS; LATTICE BOLTZMANN METHOD; MAGNETIC FIELD STRENGTHS; MAGNETIZATION FORCE; NON EQUILIBRIUM; NONISOTHERMAL FLOWS; NONUNIFORM; QUENCHING EFFICIENCY; SECOND-ORDER ACCURACY; SLIP VELOCITY; SQUARE CAVITY; TEMPERATURE BOUNDARY; THERMAL LATTICE BOLTZMANN METHOD;

APPROXIMATION THEORY; ATMOSPHERIC ELECTRICITY; BOUNDARY CONDITIONS; DISTRIBUTION FUNCTIONS; DROP FORMATION; LOCATION; LORENTZ FORCE; MAGNETIC MATERIALS; MAGNETIZATION; MAGNETS; NATURAL CONVECTION; NUMERICAL METHODS; OPTICAL FILTERS; QUENCHING;

MAGNETIC FIELD EFFECTS;

EID: 70350516636     PISSN: 16741056     EISSN: None     Source Type: Journal    
DOI: 10.1088/1674-1056/18/10/004     Document Type: Article

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