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March 2020
This article was originally published in
Journal of Heat Transfer
ISSN 0022-1481
EISSN 1528-8943
In this Issue
Guest Editorial
Heat Transfer Photogallery
J. Heat Transfer. March 2020, 142(3): 030301.
doi: https://doi.org/10.1115/1.4046119
Topics:
Heat transfer
Special Section Photogallery
Frost Halo Dynamics on Superhydrophobic Surfaces
J. Heat Transfer. March 2020, 142(3): 030901.
doi: https://doi.org/10.1115/1.4046148
Topics:
Dynamics (Mechanics)
,
Drops
,
Freezing
,
Condensed matter
,
Diffusion (Physics)
,
Vapors
,
Condensation
,
Evaporation
,
Microscale devices
,
Aerospace industry
Bubble Behavior in Pool Boiling Heat Transfer between Two Plates with a Narrow Gap
J. Heat Transfer. March 2020, 142(3): 030902.
doi: https://doi.org/10.1115/1.4046116
Topics:
Bubbles
,
Heat transfer
,
Plates (structures)
,
Pool boiling
,
Military systems
,
Boiling
,
Ceramics
,
Copper
,
Defense industry
,
Evaporation
Surface Plasmon Resonance Imaging: A Technique to Reveal the Dropwise Condensation Mechanism
J. Heat Transfer. March 2020, 142(3): 030903.
doi: https://doi.org/10.1115/1.4046136
Topics:
Condensation
,
Imaging
,
Surface plasmon resonance
,
Drops
,
Instrumentation
,
Resolution (Optics)
,
Thin films
,
Vapors
,
Bridges (Structures)
,
Composite materials
“Dancing Droplets”: Partial Coalescence on Superhydrophobic Surfaces
J. Heat Transfer. March 2020, 142(3): 030904.
doi: https://doi.org/10.1115/1.4046118
Self-driven Liquid Metal Mollusk Oscillations
J. Heat Transfer. March 2020, 142(3): 030905.
doi: https://doi.org/10.1115/1.4046174
Topics:
Liquid metals
,
Oscillations
,
Water
,
Deformation
,
Surface tension
,
Vapors
,
China
,
Condensers (steam plant)
,
Coolants
,
Dimensions
Visualization of an Oscillating Heat Pipe with Hydraulic Diameter Far Exceeding the Conventional Maximum Hydraulic Diameter
J. Heat Transfer. March 2020, 142(3): 030906.
doi: https://doi.org/10.1115/1.4046117
Topics:
Heat pipes
,
Visualization
,
Bubbly flow
,
Flow (Dynamics)
,
Magnetohydrodynamics
,
China
,
Slug flows
,
Bubbles
,
Capillarity
,
Ethanol
Quantitative Experimental Investigation on the Flow Characteristics of Nanofluids in Turbulent Flow
J. Heat Transfer. March 2020, 142(3): 030907.
doi: https://doi.org/10.1115/1.4046184
Topics:
Flow (Dynamics)
,
Nanofluids
,
Turbulence
,
Reynolds number
,
Water
,
Fluids
,
Heat transfer
,
Nanoparticles
,
Vortices
,
Vorticity
Research Papers
Bio-Heat and Mass Transfer
Modeling and Simulation on Heat Transfer in Blood Vessels Subject to a Transient Laser Irradiation
J. Heat Transfer. March 2020, 142(3): 031201.
doi: https://doi.org/10.1115/1.4045669
Conduction
Contribution of the Hydroxyl Group on Interfacial Heat Conduction of Monohydric Alcohols: A Molecular Dynamics Study
J. Heat Transfer. March 2020, 142(3): 031401.
doi: https://doi.org/10.1115/1.4045667
Topics:
Chain
,
Crystals
,
Heat conduction
,
Heat transfer
,
Molecular dynamics
,
Simulation
,
Thermal conductivity
,
Latent heat
,
Phase change materials
,
Atoms
Forced Convection
Oscillatory Flow Induced Developing Convection in a Shallow Enclosure: Effect of Sinusoidal Bottom Wall Temperature
J. Heat Transfer. March 2020, 142(3): 031801.
doi: https://doi.org/10.1115/1.4045749
Topics:
Acoustics
,
Convection
,
Cycles
,
Flow (Dynamics)
,
Heat transfer
,
Temperature
,
Wall temperature
,
Temperature distribution
,
Reynolds number
,
Fluids
Performance Assessment of Parallel Connected Ranque–Hilsch Vortex Tubes Using Nitrogen, Oxygen, and Air With Brass and Polyamide Nozzles: An Experimental Analysis
J. Heat Transfer. March 2020, 142(3): 031802.
doi: https://doi.org/10.1115/1.4045645
Topics:
Brass (Metal)
,
Exergy
,
Flow (Dynamics)
,
Fluids
,
Nitrogen
,
Nozzles
,
Oxygen
,
Pressure
,
Temperature
,
Vortices
Unsteady Flow and Heat Transfer Characteristics of Primary and Secondary Corrugated Channels
J. Heat Transfer. March 2020, 142(3): 031803.
doi: https://doi.org/10.1115/1.4045751
Topics:
Boundary-value problems
,
Computation
,
Flow (Dynamics)
,
Heat transfer
,
Temperature
,
Unsteady flow
,
Fluids
Heat Exchangers
High Performance Loop Heat Pipe With Flat Evaporator for Energy-Saving Cooling Systems of Supercomputers
J. Heat Transfer. March 2020, 142(3): 031901.
doi: https://doi.org/10.1115/1.4045730
Topics:
Cooling
,
Heat pipes
,
Temperature
,
Water
,
Heat
,
Stress
Heat Transfer Enhancement
Numerical Simulation of Vapor–Bubble Collapse—Heat Transfer and Nonlinear Dynamics Issues
J. Heat Transfer. March 2020, 142(3): 032001.
doi: https://doi.org/10.1115/1.4045353
Topics:
Bubbles
,
Collapse
,
Heat transfer
Heat and Mass Transfer
Analysis of Clumped-Pebble Shape on Thermal Radiation and Conduction in Nuclear Beds by Subcell Radiation Model
J. Heat Transfer. March 2020, 142(3): 032101.
doi: https://doi.org/10.1115/1.4045685
Micro/Nanoscale Heat Transfer
Thermal Transport in Nanoparticle Packings Under Laser Irradiation
J. Heat Transfer. March 2020, 142(3): 032501.
doi: https://doi.org/10.1115/1.4045731
Topics:
Lasers
,
Nanoparticles
,
Packings (Cushioning)
,
Particulate matter
,
Temperature
Mixed Magnetoconvection of Nanofluids in a Long Vertical Porous Channel
J. Heat Transfer. March 2020, 142(3): 032502.
doi: https://doi.org/10.1115/1.4045670
Topics:
Flow (Dynamics)
,
Magnetic fields
,
Nanofluids
,
Nanoparticles
An Investigation on Thermal Conductivity of Fluid in a Nanochannel by Nonequilibrium Molecular Dynamics Simulations
J. Heat Transfer. March 2020, 142(3): 032503.
doi: https://doi.org/10.1115/1.4045750
Topics:
Atoms
,
Copper
,
Fluids
,
Molecular dynamics simulation
,
Nanochannels
,
Simulation
,
Surface roughness
,
Thermal conductivity
,
Poiseuille flow
Natural and Mixed Convection
Comparison of Local Heat Transfer Distribution in Between Three-Dimensional Inclined Closed and Open Cavities
J. Heat Transfer. March 2020, 142(3): 032601.
doi: https://doi.org/10.1115/1.4045753
Topics:
Cavities
,
Heat transfer
,
Rayleigh number
,
Flow (Dynamics)
Porous Media
Revisiting Forced Convection Flow Through a Porous Medium Saturated Channel Using Singular Perturbation Analysis
J. Heat Transfer. March 2020, 142(3): 032701.
doi: https://doi.org/10.1115/1.4045668
Topics:
Fluids
,
Porous materials
,
Temperature
,
Heat
,
Forced convection
Pressure Drop and Convective Heat Transfer in Different SiSiC Structures Fabricated by Indirect Additive Manufacturing
J. Heat Transfer. March 2020, 142(3): 032702.
doi: https://doi.org/10.1115/1.4045732
Gas–Solid Interfacial Heat Transfer Characteristics of Uncoated and Coated Metal Foams for Both Laminar and Turbulent Flow Regimes
J. Heat Transfer. March 2020, 142(3): 032703.
doi: https://doi.org/10.1115/1.4045757
Topics:
Foams (Chemistry)
,
Heat transfer
,
Metal foams
,
Porosity
,
Turbulence
,
Flow (Dynamics)
,
Heat transfer coefficients
,
Laminar flow
Radiative Heat Transfer
On the Wave Speed of Thermal Radiation Inside and Near the Boundary of an Absorbing Material
J. Heat Transfer. March 2020, 142(3): 032801.
doi: https://doi.org/10.1115/1.4045665
Topics:
Photons
,
Radiation (Physics)
,
Thermal radiation
,
Vacuum
,
Waves
,
Temperature
,
Refractive index
,
Signals
,
Wavelength
,
Electromagnetic fields
Two-Phase Flow and Heat Transfer
Exergetic Relationship Between the Thermal Properties of Direct Contact Membrane Distillation
J. Heat Transfer. March 2020, 142(3): 033001.
doi: https://doi.org/10.1115/1.4045748
Topics:
Exergy
,
Membranes
,
Temperature
,
Simulation
,
Thermal properties
Technical Briefs
Benchmark Solutions of Three-Dimensional Radiative Transfer in Nongray Media Using Line-by-Line Integration
J. Heat Transfer. March 2020, 142(3): 034501.
doi: https://doi.org/10.1115/1.4045666
Topics:
Carbon dioxide
,
Databases
,
Heat
,
Heat flux
,
Radiative heat transfer
,
Resolution (Optics)
,
Water
,
Temperature
,
Radiation (Physics)
,
Finite volume methods
Thermal Step Response of N-Layer Composite Walls—Accurate Approximative Formulas
J. Heat Transfer. March 2020, 142(3): 034502.
doi: https://doi.org/10.1115/1.4045642
Discussion
Discussion: “Simultaneous Effects of Nonlinear Mixed Convection and Radiative Flow Due to Riga-Plate With Double Stratification” (Hayat, T., Ullah, I., Alsaedi, A., Ahamad, B., 2018, ASME J. Heat Transfer, 140(10), p. 102008)
J. Heat Transfer. March 2020, 142(3): 035501.
doi: https://doi.org/10.1115/1.4045684
Topics:
Flow (Dynamics)
,
Heat transfer
,
Mixed convection
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