Analysis of solidification and physical behavior of nanomaterial during unsteady process

Ammar A. Melaibari; Turki AlQemlas; Nidal H. Abu-Hamdeh; Hosam A. Saad; Amira M. Hussin

doi:10.1142/S0217979223502557

Analysis of solidification and physical behavior of nanomaterial during unsteady process

Ammar A. Melaibari, Turki AlQemlas, Nidal H. Abu-Hamdeh, Hosam A. Saad, Amira M. Hussin

Mathematics

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Alumina nanoparticles with various shapes have been loaded into water to accelerate the freezing phenomena within closed cavity. The mathematical model contains unsteady conduction equation in the existence of unsteady source terms for phase changing. In this model, three properties of NEPCM are involved and for calculating those parameters, single phase approximation has been utilized. By using FEM, outputs for impact of shape and volume of nanoparticles have been reported. Also, the method was verified by comparing the outputs with the previous data. Increasing the volume of nanoparticles to twice the range makes the needed time decrease by about 13.82%. When ϕ =0.02 makes freezing time decrease by about 3.92%.

Original language	English
Article number	2350255
Journal	International Journal of Modern Physics B
Volume	37
Issue number	29
DOIs	https://doi.org/10.1142/S0217979223502557
State	Published - 20 Nov 2023

Keywords

Closed cavity
finite element method
nanoparticle
solidification
water

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10.1142/S0217979223502557

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title = "Analysis of solidification and physical behavior of nanomaterial during unsteady process",

abstract = "Alumina nanoparticles with various shapes have been loaded into water to accelerate the freezing phenomena within closed cavity. The mathematical model contains unsteady conduction equation in the existence of unsteady source terms for phase changing. In this model, three properties of NEPCM are involved and for calculating those parameters, single phase approximation has been utilized. By using FEM, outputs for impact of shape and volume of nanoparticles have been reported. Also, the method was verified by comparing the outputs with the previous data. Increasing the volume of nanoparticles to twice the range makes the needed time decrease by about 13.82\%. When ϕ =0.02 makes freezing time decrease by about 3.92\%.",

keywords = "Closed cavity, finite element method, nanoparticle, solidification, water",

author = "Melaibari, \{Ammar A.\} and Turki AlQemlas and Abu-Hamdeh, \{Nidal H.\} and Saad, \{Hosam A.\} and Hussin, \{Amira M.\}",

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T1 - Analysis of solidification and physical behavior of nanomaterial during unsteady process

AU - Melaibari, Ammar A.

AU - AlQemlas, Turki

AU - Abu-Hamdeh, Nidal H.

AU - Saad, Hosam A.

AU - Hussin, Amira M.

N1 - Publisher Copyright: © World Scientific Publishing Company.

PY - 2023/11/20

Y1 - 2023/11/20

N2 - Alumina nanoparticles with various shapes have been loaded into water to accelerate the freezing phenomena within closed cavity. The mathematical model contains unsteady conduction equation in the existence of unsteady source terms for phase changing. In this model, three properties of NEPCM are involved and for calculating those parameters, single phase approximation has been utilized. By using FEM, outputs for impact of shape and volume of nanoparticles have been reported. Also, the method was verified by comparing the outputs with the previous data. Increasing the volume of nanoparticles to twice the range makes the needed time decrease by about 13.82%. When ϕ =0.02 makes freezing time decrease by about 3.92%.

AB - Alumina nanoparticles with various shapes have been loaded into water to accelerate the freezing phenomena within closed cavity. The mathematical model contains unsteady conduction equation in the existence of unsteady source terms for phase changing. In this model, three properties of NEPCM are involved and for calculating those parameters, single phase approximation has been utilized. By using FEM, outputs for impact of shape and volume of nanoparticles have been reported. Also, the method was verified by comparing the outputs with the previous data. Increasing the volume of nanoparticles to twice the range makes the needed time decrease by about 13.82%. When ϕ =0.02 makes freezing time decrease by about 3.92%.

KW - Closed cavity

KW - finite element method

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Analysis of solidification and physical behavior of nanomaterial during unsteady process

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