![]() ![]() 297-315, 2006.I came across the coding below that is very useful for my work. Kakac, Gaseous Flow in Microconduits with Viscous Dissipation, Int. Mezaache, Analytical Prediction for Slip Flow-Heat Transfer in Microtube and Parallel Plate Microchannel Including Viscous Dissipation, Int. Tian, Simulation of Thermal Micro-Flow using Lattice Boltzmann Method with Langmuir Slip Model, Int. Reese, The Effect of Gaseous Slip on Microscale Heat Transfer: An Extended Graetz Problem, Int. Ameel, The Effect of Creep Flow on Two-Dimensional Isoflux Microchannels, Int. Ameel, Microtube Gas Flows with Second-Order Slip Flow and Temperature Jump Boundary Conditions, Int. Tai, Effects of Viscous Dissipation on Slip-Flow Heat Transfer in a Micro Annulus, Int. Laminar Forced Convection Slip-Flow in a Micro-Annulus Between Two Concentric Cylinders, Int. Cetegen, Prediction of Temperature Distribution and Nusselt Number in Rectangular Microchannels at Wall Slip Condition for all Versions of Constant Heat Flux, Int. Tercan, Slip-Flow and Heat Transfer in Rectangular Microchannels with Constant Wall Temperature, Int. Kuddusi, Prediction of Temperature Distribution and Nusselt Number in Rectangular Microchannels at Wall Slip Condition for all Versions of Constant Wall Temperature, Int. Chen, Slip Flow Heat Transfer in Microchannel with Viscous Dissipation, Heat Mass Transfer, vol. ![]() Joeng, Extended Graetz Problem Including Streamwise Conduction and Viscous Dissipation in Microchannel, Int. G Hadjiconstantinou, Dissipation in Small Scale Gaseous Flows, Journal of Heat Transfer, vol. Satapathy, Slip Flow Heat Transfer in an Infinite Microtube with Axial Conduction, Int. Avcı, Heat and Fluid Flow Characteristics of Gases in Micropipes, Int. Kakaç, Slip-Flow Heat Transfer in Microtubes with Axial Conduction and Viscous Dissipation–An Extended Graetz Problem, Int. Communication in Heat and Mass Transfer, vol. Kakaç, Fluid flow in microtubes with axial conduction including rarefaction and viscous dissipation, Int. Bayazitoglu, Heat Transfer in Microtubes with Viscous Dissipation, Int. Yazicioglu, A Numerical Study of Single-Phase Convective Heat Transfer in Microtubes for Slip Flow, Int. Drossinos, Slip Flow Heat Transfer in Circular Tubes, Int. SNIP takes into account characteristics of the source's subject field, which is the set of documents citing that source. It helps you make a direct comparison of sources in different subject fields. SNIP measures a source’s contextual citation impact by weighting citations based on the total number of citations in a subject field. Source Normalized Impact per Paper (SNIP) 2021: 0.602 ℹ Source Normalized Impact per Paper(SNIP): SJR is a measure of scientific influence of journals that accounts for both the number of citations received by a journal and the importance or prestige of the journals where such citations come from It measures the scientific influence of the average article in a journal, it expresses how central to the global scientific discussion an average article of the journal is. It is based on the idea that 'all citations are not created equal'. The SJR is a size-independent prestige indicator that ranks journals by their 'average prestige per article'. SCImago Journal Rank (SJR) 2021: 0.297 ℹ SCImago Journal Rank (SJR): CiteScore is the number of citations received by a journal in one year to documents published in the three previous years, divided by the number of documents indexed in Scopus published in those same three years. ![]()
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