Handbook of numerical heat transfer

A comprehensive presentation is given of just about all numerical strategies that square measure appropriate for the analysis of the assorted heat thwartwise and fluid flow issues that occur in analysis, practice, and university instruction. once reviewing basic methodologies, the subsequent topics square measure covered: finite distinction and finite component strategies for parabolic, elliptic, and hyperbolic systems; a comparative appraisal of finite distinction versus finite component strategies; integral and integrodifferential systems; perturbation methods; Monte Carlo methods; finite analytic methods; moving boundary problems; inverse problems; graphical show methods; grid generation methods; and programing methods for supercomputers. [1]

Radiation Heat Transfer

Revised to incorporate additional info on analytical models for wavelength independence, Radiation Heat Transfer, increased Edition has been rearranged, providing issues inside every chapter instead of at the top of the book. Written by Ephraim M. Sparrow, a scholarly person World Health Organization works on a really broad vary of issues that encompasses the majority applied science topics, the book presents key ideas while not being thoroughgoing. Sparrow oversees the Laboratory for warmth Transfer and Fluid Flow apply, whose operate in to undertake each industrially bases and elementary issues that fall inside the bounds of warmth transfer and fluid flow. [2]

Heat transfer characteristics of nanofluids: a review

Research in convective heat transfer victimization suspensions of nanometer-sized solid particles in base liquids started solely over the past decade. Recent investigations on nanofluids, per se suspensions are typically referred to as, indicate that the suspended nanoparticles markedly modification the transport properties and warmth transfer characteristics of the suspension. This review summarizes recent analysis on fluid flow and warmth transfer characteristics of nanofluids in forced and free convection flows and identifies opportunities for future research. [3]

Quantum control of excitons for reversible heat transfer

Lasers, photovoltaics, and thermoelectrically-pumped lightweight emitting diodes area unit physics machines that use excitons (electron-hole pairs) because the operating medium. the warmth transfers in such devices area unit extremely irreversible, resulting in low efficiencies. Here we tend to predict that reversible heat transfers between a quantum-dot exciton and its phonon surroundings will be elicited by optical device pulses. we tend to calculate the warmth transfer once a quantum-dot exciton is driven by a chirped optical device pulse. The changeableness of this heat transfer is quantified by the potency of a engine within which it forms the recent stroke, that we tend to predict to achieve ninety fifth of the Sadi Carnot limit. This performance is achieved by victimisation the time-dependent laser-dressing of the exciton to manage the warmth current and exciton temperature. [4]

Dissipative Heat Transfer of Micropolar Hydromagnetic Variable Electric Conductivity Fluid Past Inclined Plate with Joule Heating and Non-uniform Heat Generation

Computational simulations of hydromagnetic dissipative heat transfer of variable electrical conduction of micropolar fluid flow and non-uniform heat absorption or generation with joule heating are studied during this work. The flow past Associate in Nursing inclined surface with an unvarying heat flux. The remodeled dimensionless equations of the governing model are resolved by Runge-Kutta algorithmic program in addition to shooting theme to depict the dimensionless temperature, microrotation and speed distributions at the border layer. The substantial bodily quantities of the flow are given. The results depict that the importance of the constant of the skin friction and also the Nusselt range will increase for uneven electrical conduction and non- homogeneous  sink or supply at the plate. [5]

Reference

[1] Minkowycz, W.J., Sparrow, E.M., Schneider, G.E. and Pletcher, R.H., 1988. Handbook of numerical heat transfer. New York, Wiley-Interscience, 1988, 1035 p. No individual items are abstracted in this volume. (Web Link)

[2] Sparrow, E.M., 2018. Radiation heat transfer. Routledge. (Web Link)

[3] Wang, X.Q. and Mujumdar, A.S., 2007. Heat transfer characteristics of nanofluids: a review. International journal of thermal sciences, 46(1), (Web Link)

[4] Quantum control of excitons for reversible heat transfer
Conor N. Murphy & Paul R. Eastham
Communications Physics volume 2, Article number: 120 (2019) (Web Link)

[5] O. Salawu, S. and O. Fatunmbi, E. (2017) “Dissipative Heat Transfer of Micropolar Hydromagnetic Variable Electric Conductivity Fluid Past Inclined Plate with Joule Heating and Non-uniform Heat Generation”, Asian Journal of Physical and Chemical Sciences, 2(1), (Web Link)