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Modeling and simulations of nanofluids using classical molecular dynamics: Particle size and temperature effects on thermal conductivity

Version 2 2024-06-13, 13:16
Version 1 2019-09-17, 11:36
journal contribution
posted on 2024-06-13, 13:16 authored by EM Achhal, H Jabraoui, S Zeroual, H Loulijat, A Hasnaoui, S Ouaskit
© 2018 The Society of Powder Technology Japan We use molecular dynamics simulations to investigate the thermal conductivity of argon-based nanofluid with copper nanoparticles through the Green-Kubo formalism. To describe the interaction between argon-argon atoms, we used the well-known Lennard-Jones (L-J) potential, while the copper–copper interactions are modeled using the embedded atom method (EAM) potential that takes the metallic bonding into account. The thermal conductivity of the pure argon liquid obtained in the present simulation agreed with available experimental results. In the case of nanofluid, our simulation predicted thermal conductivity values larger than those found by the existing analytical models, but in a good accordance with experimental results. This implies that our simulation is more adequate, to describe the thermal conductivity of nanofluids than the previous analytical models. The efficiency of nanofluids is improved and the thermal conductivity enhancement is appeared when the particle size and temperature increase.

History

Journal

Advanced Powder Technology

Volume

29

Pagination

2434-2439

Location

Piscataway N.J.

ISSN

0921-8831

eISSN

1568-5527

Publication classification

C1 Refereed article in a scholarly journal

Issue

10

Publisher

Elsevier