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October 2017
This article was originally published in
Journal of Heat Transfer
ISSN 0022-1481
EISSN 1528-8943
Research Papers
Evaporation, Boiling, and Condensation
Effect of Surface Roughness on Pool Boiling Heat Transfer of Water on a Superhydrophilic Aluminum Surface
J. Heat Transfer. October 2017, 139(10): 101501.
doi: https://doi.org/10.1115/1.4036599
Topics:
Aluminum
,
Boiling
,
Copper
,
Critical heat flux
,
Heat transfer
,
Pool boiling
,
Surface roughness
,
Water
,
Heat transfer coefficients
Forced Convection
Real-Time Determination of Convective Heat Transfer Coefficient Via Thermoelectric Modules
J. Heat Transfer. October 2017, 139(10): 101701.
doi: https://doi.org/10.1115/1.4036734
Topics:
Convection
,
Temperature
Prandtl Number Effect on the Laminar Convective Heat Transfer From a Rotating Disk
J. Heat Transfer. October 2017, 139(10): 101702.
doi: https://doi.org/10.1115/1.4036729
Topics:
Convection
,
Design
,
Disks
,
Heat transfer
,
Natural convection
,
Prandtl number
,
Rotating disks
,
Temperature
,
Water
,
Fluids
Experimental Investigation and Three-Dimensional Numerical Analysis of Ferroconvection Through Horizontal Tube Under Magnetic Field of Fixed Parallel Magnet Bars
Yahya Sheikhnejad, Mir Mehrdad Hosseini, Antonio Teixeira, Ali Shahpari, Reza Hosseini, Majid Saffar Avval
J. Heat Transfer. October 2017, 139(10): 101703.
doi: https://doi.org/10.1115/1.4036620
Topics:
Ferrofluids
,
Heat transfer
,
Magnetic fields
,
Magnets
,
Numerical analysis
,
Pipes
,
Porous materials
,
Fluids
Heat Exchangers
Thermoeconomic Optimization and Comparison of Plate-Fin Heat Exchangers Using Louver, Offset Strip, Triangular and Rectangular Fins Applied in 200 kW Microturbines
J. Heat Transfer. October 2017, 139(10): 101801.
doi: https://doi.org/10.1115/1.4036618
Topics:
Design
,
Heat exchangers
,
Optimization
,
Strips
,
Pressure drop
,
Microturbines
,
Fins
,
Pareto optimization
,
Flow (Dynamics)
,
Cycles
Heat and Mass Transfer
Selection and Characterization of Green Propellants for Micro-Resistojets
J. Heat Transfer. October 2017, 139(10): 102001.
doi: https://doi.org/10.1115/1.4036619
Topics:
Fluids
,
Pressure
,
Propellants
,
Safety
,
Water
,
Temperature
Fuzzy Adaptive Predictive Inverse for Nonlinear Transient Heat Transfer Process
J. Heat Transfer. October 2017, 139(10): 102002.
doi: https://doi.org/10.1115/1.4036573
Topics:
Heat flux
,
Temperature
,
Optimization
,
Transient heat transfer
,
Heat transfer
,
Thermal properties
Dependence of Film Cooling Effectiveness on Three-Dimensional Printed Cooling Holes
J. Heat Transfer. October 2017, 139(10): 102003.
doi: https://doi.org/10.1115/1.4036509
Application of Houston's Method to the Calculation of the Direction-Dependent Thermal Conductivity in Finite Crystals at Low Temperatures
J. Heat Transfer. October 2017, 139(10): 102004.
doi: https://doi.org/10.1115/1.4036601
Topics:
Crystals
,
Low temperature
,
Phonons
,
Thermal conductivity
,
Temperature gradient
,
Temperature
The Effect of Naturally Developing Roughness on the Mass Transfer in Pipes Under Different Reynolds Numbers
J. Heat Transfer. October 2017, 139(10): 102005.
doi: https://doi.org/10.1115/1.4036728
Topics:
Mass transfer
,
Pipes
,
Reynolds number
,
Surface roughness
Micro/Nanoscale Heat Transfer
Selecting Optimal Parallel Microchannel Configuration(s) for Active Hot Spot Mitigation of Multicore Microprocessors in Real Time
J. Heat Transfer. October 2017, 139(10): 102401.
doi: https://doi.org/10.1115/1.4036643
Topics:
Cooling
,
Flow (Dynamics)
,
Fluids
,
Heat
,
Microchannels
,
Nanofluids
,
Particulate matter
,
Stress
,
Temperature
,
Water
Natural and Mixed Convection
Dual Solutions for Opposing Mixed Convection in Porous Media
J. Heat Transfer. October 2017, 139(10): 102501.
doi: https://doi.org/10.1115/1.4036727
Porous Media
Forced Convection in a Bidisperse Porous Medium Embedded in a Circular Pipe
J. Heat Transfer. October 2017, 139(10): 102601.
doi: https://doi.org/10.1115/1.4036574
Topics:
Heat transfer
,
Pipes
,
Porous materials
,
Temperature
,
Forced convection
,
Boundary-value problems
,
Fluids
,
Momentum
,
Temperature distribution
,
Permeability
Radiative Heat Transfer
Solving Nongray Boltzmann Transport Equation in Gallium Nitride
J. Heat Transfer. October 2017, 139(10): 102701.
doi: https://doi.org/10.1115/1.4036616
Topics:
Gallium nitride
,
Phonons
,
Temperature
,
Relaxation (Physics)
,
Simulation
Technical Brief
Effects of Uniform Heat Flux and Velocity-Slip Conditions at Interface on Heat Transfer Phenomena of Smooth Spheres in Newtonian Fluids
J. Heat Transfer. October 2017, 139(10): 104501.
doi: https://doi.org/10.1115/1.4036598
Topics:
Boundary-value problems
,
Fluids
,
Heat flux
,
Heat transfer
Thermomagnetic Convection Around a Current-Carrying Wire in Ferrofluid
J. Heat Transfer. October 2017, 139(10): 104502.
doi: https://doi.org/10.1115/1.4036688
Topics:
Convection
,
Ferrofluids
,
Heat transfer
,
Temperature
,
Wire
,
Magnetic fields
,
Flow (Dynamics)
Hybrid Atomistic-Continuum Simulation of Nanostructure Defect-Induced Bubble Growth
J. Heat Transfer. October 2017, 139(10): 104503.
doi: https://doi.org/10.1115/1.4036692
Topics:
Bubbles
,
Computational fluid dynamics
,
Copper
,
Simulation
,
Wedges
,
Density
,
Vapors
,
Temperature
Fully Developed Laminar Forced Convection in a Circular Duct for Herschel–Bulkley Fluids With Viscous Dissipation and Axial Heat Conduction
J. Heat Transfer. October 2017, 139(10): 104504.
doi: https://doi.org/10.1115/1.4036690
Topics:
Ducts
,
Energy dissipation
,
Fluids
,
Forced convection
,
Heat conduction
,
Heat flux
,
Temperature
,
Boundary-value problems
Second Law Analysis of Boundary Layer Flow With Variable Fluid Properties
J. Heat Transfer. October 2017, 139(10): 104505.
doi: https://doi.org/10.1115/1.4036645
Topics:
Boundary layers
,
Entropy
,
Flow (Dynamics)
,
Fluids
,
Heat transfer
,
Viscosity
Effect of Thermal Conductivity Ratio on Laminar Double-Diffusive Free Convection in a Porous Cavity
J. Heat Transfer. October 2017, 139(10): 104506.
doi: https://doi.org/10.1115/1.4036617
Topics:
Cavities
,
Heat
,
Mass transfer
,
Natural convection
,
Thermal conductivity
,
Porous materials
,
Convection
Discussion
Discussion: “Magnetohydrodynamics Thermocapillary Marangoni Convection Heat Transfer of Power-Law Fluids Driven by Temperature Gradient” (Lin, Y., Zheng, L., and Zhang, X., 2013, ASME J. Heat Transfer, 135(5), p. 051702)
J. Heat Transfer. October 2017, 139(10): 105501.
doi: https://doi.org/10.1115/1.4036733
Topics:
Convection
,
Fluids
,
Heat transfer
,
Magnetohydrodynamics
,
Temperature gradient
,
Shear stress
,
Heat
,
Mass transfer