Literature DB >> 15524799

Model for heat conduction in nanofluids.

D Hemanth Kumar1, Hrishikesh E Patel, V R Rajeev Kumar, T Sundararajan, T Pradeep, Sarit K Das.   

Abstract

A comprehensive model has been proposed to account for the large enhancement of thermal conductivity in nanofluids and its strong temperature dependence, which the classical Maxwellian theory has been unable to explain. The dependence of thermal conductivity on particle size, concentration, and temperature has been taken care of simultaneously in our treatment. While the geometrical effect of an increase in surface area with a decrease in particle size, rationalized using a stationary particle model, accounts for the conductivity enhancement, a moving particle model developed from the Stokes-Einstein formula explains the temperature effect. Predictions from the combined model agree with the experimentally observed values of conductivity enhancement of nanofluids.

Year:  2004        PMID: 15524799     DOI: 10.1103/PhysRevLett.93.144301

Source DB:  PubMed          Journal:  Phys Rev Lett        ISSN: 0031-9007            Impact factor:   9.161


  18 in total

1.  Nanofluid Dynamics of Flexible Polymeric Nanoparticles Under Wall Confinement.

Authors:  Samaneh Farokhirad; N Ramakrishnan; David M Eckmann; Portonovo S Ayyaswamy; Ravi Radhakrishnan
Journal:  J Heat Transfer       Date:  2019-03-27       Impact factor: 2.021

2.  Instantaneous ballistic velocity of suspended Brownian nanocrystals measured by upconversion nanothermometry.

Authors:  Carlos D S Brites; Xiaoji Xie; Mengistie L Debasu; Xian Qin; Runfeng Chen; Wei Huang; João Rocha; Xiaogang Liu; Luís D Carlos
Journal:  Nat Nanotechnol       Date:  2016-07-04       Impact factor: 39.213

3.  Nanoparticle transport phenomena in confined flows.

Authors:  Ravi Radhakrishnan; Samaneh Farokhirad; David M Eckmann; Portonovo S Ayyaswamy
Journal:  Adv Heat Transf       Date:  2019-10-04

4.  Hybrid Nanofluid Thermal Conductivity and Optimization: Original Approach and Background.

Authors:  Jake Wohld; Joshua Beck; Kallie Inman; Michael Palmer; Marcus Cummings; Ryan Fulmer; Saeid Vafaei
Journal:  Nanomaterials (Basel)       Date:  2022-08-18       Impact factor: 5.719

5.  Mesomorphic lamella rolling of au in vacuum.

Authors:  Chang-Ning Huang; Shuei-Yuan Chen; Pouyan Shen
Journal:  Nanoscale Res Lett       Date:  2009-07-18       Impact factor: 4.703

Review 6.  Carbon-Based Nanofluids and Their Advances towards Heat Transfer Applications-A Review.

Authors:  Naser Ali; Ammar M Bahman; Nawaf F Aljuwayhel; Shikha A Ebrahim; Sayantan Mukherjee; Ali Alsayegh
Journal:  Nanomaterials (Basel)       Date:  2021-06-21       Impact factor: 5.076

7.  Review of thermo-physical properties, wetting and heat transfer characteristics of nanofluids and their applicability in industrial quench heat treatment.

Authors:  Gopalan Ramesh; Narayan Kotekar Prabhu
Journal:  Nanoscale Res Lett       Date:  2011-04-14       Impact factor: 4.703

8.  A new heat propagation velocity prevails over Brownian particle velocities in determining the thermal conductivities of nanofluids.

Authors:  Kenneth D Kihm; Chan Hee Chon; Joon Sik Lee; Stephen Us Choi
Journal:  Nanoscale Res Lett       Date:  2011-04-27       Impact factor: 4.703

9.  Enhancements of thermal conductivities with Cu, CuO, and carbon nanotube nanofluids and application of MWNT/water nanofluid on a water chiller system.

Authors:  Minsheng Liu; Mark Chingcheng Lin; Chichuan Wang
Journal:  Nanoscale Res Lett       Date:  2011-04-05       Impact factor: 4.703

10.  Experimental and theoretical studies of nanofluid thermal conductivity enhancement: a review.

Authors:  Clement Kleinstreuer; Yu Feng
Journal:  Nanoscale Res Lett       Date:  2011-03-16       Impact factor: 4.703
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