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- Convection, Stability and Turbulence
- Experiments on Rayleigh–Bénard Convection, Magnetoconvection
- Turbulent Dynamos at Low Magnetic Prandtl Number
- The Influence of a Magnetic Field on Turbulent Heat Transfer of a High
- 7(11), November, 2018 ISSN: 2277-9655
- Locally Variable Turbulent Prandtl Number Considerations on The
- Effect of Noble Gas Mixtures on the Performance of Regenerative-Type Cryocoolers Analytical Estimate
- Computation of Turbulent Prandtl Number for Mixed Convection Around a Heated Cylinder
- On Numerical Simulation of Cavitating Flows Under Thermal Regime
- Turbulent Geodynamo Simulations: a Leap Towards Earth's Core
- SIGNIFICANCE of DIMENSIONLESS NUMBERS in the FLUID MECHANICS Sobia Sattar, Siddra Rana Department of Mathematics, University of Wah [email protected]
- Fluid Numbers
- Thermal Performance of Shell and Tube Heat Exchanger Using PG
- A Logarithmic Turbulent Heat Transfer Model in Applications with Liquid Metals for Pr = 0.01–0.025
- The Influence of Prandtl Number and Surface Roughness on the Resistance of the Laminar Sub-Layer to Momentum and Heat Transfer
- Abstracts Invited Speakers
- On Upper Bounds for Infinite Prandtl Number Convection with Or Without Rotation
- Thermophysical Properties of Helium-4 from 0.8 to 1500 K with Pressures to 2000 Mpa
- Numerical Study of Dynamo Action at Low Magnetic Prandtl Numbers
- Influence of Certain Thermo-Physical Properties on Prandtl Number of Water Based Nanofluids
- Thermodynamic and Transport Properties of Air and the Combustion Products of Natural Gas and of Astm-A-1 Fuel with Air
- High-Rayleigh-Number Convection in a Fluid-Saturated Porous Layer
- Turbulent Rayleigh-Benard Convection in Low Prandtl-Number Fluids
- Cavitation and Heat Transfer Over Micro Pin Fins
- Laminar Starting Plumes in High-Prandtl-Number Fluids
- ORIGIN of MAGNETIC FIELD in the INTRACLUSTER MEDIUM: PRIMORDIAL OR ASTROPHYSICAL? Jungyeon Cho1 Draft Version August 3, 2018
- Optimization of Turbulent Prandtl Number in Turbulent, Wall Bounded Flows Donald Edward Bernard University of Vermont
- Convection Heat Transfer Introduction
- Low Prandtl Number Thermal-Hydraulics*
- MHD Turbulence at Moderate Magnetic Reynolds Number
- Effect of Prandtl Number on Free Convection in a Solar Collector Filled with Nanofluid
- Simulations of the Near-Wall Heat Transfer at Medium Prandtl Numbers
- Reversed Dynamo at Small Scales and Large Magnetic
- Facing Step Is Therefore of Great Interest for Heat Transfer Applica- Tions Using Liquid Metals As a Working fluid
- The Smallest Thermal Scales in a Turbulent Channel Flow at Prandtl Number 1
- Role of Turbulent Prandtl Number on Heat Flux at Hypersonic Mach Numbers
- Cavitation of Mercury in a Centrifugal Pump
- On Numerical Simulation of Cavitating Flows Under Thermal Regime Damien Colombet, Eric Goncalves Da Silva, Regiane Fortes Patella
- Heat Transfer to Or from a Fluid Flowing Through a Tube
- Effect of Prandtl Number on Forced Convection in a Two Sided Open Enclosure Using Nanofluid
- Prandtl Number in Classical Hard-Sphere and One-Component Plasma Fluids
- Intermittent Turbulent Dynamo at Very Low and High Magnetic Prandtl Numbers
- Dependence on Magnetic Prandtl Number
- Prandtl Number Effect on Assisted Convective Heat Transfer Through a Solar Collector
- Viscous Effects on the Position of Cavitation Separation from Smooth. Bodies
- Nelium, a Refrigerant with High Potential for the Temperature Range Between 27 and 70 K
- Field Synergy Number Versus Stanton Number M