Staff View: Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study

Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study

This article investigates how nanocellulose might improve heat transmission by creating and analyzing nanofluids. Interest has been sparked by the improved thermal properties of nanofluids, which are made up of nanoparticles scattered throughout base fluids. In this work, nanofluids with various vol...

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Main Authors:	Aqeel A.A.K.A., Hajjaj S.S.H., Mohamed H., Obeidat F.S.
Other Authors:	57680214800
Format:	Conference paper
Published:	Springer Science and Business Media Deutschland GmbH 2025
Subjects:	Air Conditioning Density Distilled Water Stability Temperature Thermal Conductivity Thermal Insulation Volume Air curtains Cell engineering Nanocellulose Nanoclay Nanoparticles Thermal conductivity of solids Cellulose nanocrystal Distilled water Heat transfer performance Heat transmission Nano-cellulose Nanofluids Property Thermal Volume concentration Cellulose nanocrystals
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id	my.uniten.dspace-36976
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spelling	my.uniten.dspace-369762025-03-03T15:46:16Z Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study Aqeel A.A.K.A. Hajjaj S.S.H. Mohamed H. Obeidat F.S. 57680214800 55812832600 57136356100 57201367589 Air Conditioning Density Distilled Water Stability Temperature Thermal Conductivity Thermal Insulation Volume Air curtains Cell engineering Nanocellulose Nanoclay Nanoparticles Thermal conductivity of solids Cellulose nanocrystal Density Distilled water Heat transfer performance Heat transmission Nano-cellulose Nanofluids Property Thermal Volume concentration Cellulose nanocrystals This article investigates how nanocellulose might improve heat transmission by creating and analyzing nanofluids. Interest has been sparked by the improved thermal properties of nanofluids, which are made up of nanoparticles scattered throughout base fluids. In this work, nanofluids with various volume concentrations of cellulose nanocrystals (CNC) are made by dispersing the CNC in distilled water and ethylene glycol. Stirring and ultrasonication are used to guarantee stability throughout the preparation process. Thermal conductivity experiments show that the presence of CNC nanoparticles significantly increases thermal conductivity, indicating a proportionate connection between volume concentration and temperature. According to density measurements, temperature and volume concentration affect nanofluid density, with more significant concentrations and lower temperatures resulting in greater density. Overall, this study demonstrates the potential of nanofluids based on nanocellulose to improve heat transmission while revealing essential details about their production, stability, and thermal characteristics. These discoveries substantially influence environmental science, medicine, and materials engineering. They also offer opportunities for improved thermal management systems. ? The Author(s), under exclusive license to Springer Nature Switzerland AG 2024. Final 2025-03-03T07:46:16Z 2025-03-03T07:46:16Z 2024 Conference paper 10.1007/978-3-031-70684-4_6 2-s2.0-85210890818 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85210890818&doi=10.1007%2f978-3-031-70684-4_6&partnerID=40&md5=3ed6769f5f151e3a6fa9232cb0371b41 https://irepository.uniten.edu.my/handle/123456789/36976 1132 LNNS 75 83 Springer Science and Business Media Deutschland GmbH Scopus
institution	Universiti Tenaga Nasional
building	UNITEN Library
collection	Institutional Repository
continent	Asia
country	Malaysia
content_provider	Universiti Tenaga Nasional
content_source	UNITEN Institutional Repository
url_provider	http://dspace.uniten.edu.my/
topic	Air Conditioning Density Distilled Water Stability Temperature Thermal Conductivity Thermal Insulation Volume Air curtains Cell engineering Nanocellulose Nanoclay Nanoparticles Thermal conductivity of solids Cellulose nanocrystal Density Distilled water Heat transfer performance Heat transmission Nano-cellulose Nanofluids Property Thermal Volume concentration Cellulose nanocrystals
spellingShingle	Air Conditioning Density Distilled Water Stability Temperature Thermal Conductivity Thermal Insulation Volume Air curtains Cell engineering Nanocellulose Nanoclay Nanoparticles Thermal conductivity of solids Cellulose nanocrystal Density Distilled water Heat transfer performance Heat transmission Nano-cellulose Nanofluids Property Thermal Volume concentration Cellulose nanocrystals Aqeel A.A.K.A. Hajjaj S.S.H. Mohamed H. Obeidat F.S. Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study
description	This article investigates how nanocellulose might improve heat transmission by creating and analyzing nanofluids. Interest has been sparked by the improved thermal properties of nanofluids, which are made up of nanoparticles scattered throughout base fluids. In this work, nanofluids with various volume concentrations of cellulose nanocrystals (CNC) are made by dispersing the CNC in distilled water and ethylene glycol. Stirring and ultrasonication are used to guarantee stability throughout the preparation process. Thermal conductivity experiments show that the presence of CNC nanoparticles significantly increases thermal conductivity, indicating a proportionate connection between volume concentration and temperature. According to density measurements, temperature and volume concentration affect nanofluid density, with more significant concentrations and lower temperatures resulting in greater density. Overall, this study demonstrates the potential of nanofluids based on nanocellulose to improve heat transmission while revealing essential details about their production, stability, and thermal characteristics. These discoveries substantially influence environmental science, medicine, and materials engineering. They also offer opportunities for improved thermal management systems. ? The Author(s), under exclusive license to Springer Nature Switzerland AG 2024.
author2	57680214800
author_facet	57680214800 Aqeel A.A.K.A. Hajjaj S.S.H. Mohamed H. Obeidat F.S.
format	Conference paper
author	Aqeel A.A.K.A. Hajjaj S.S.H. Mohamed H. Obeidat F.S.
author_sort	Aqeel A.A.K.A.
title	Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study
title_short	Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study
title_full	Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study
title_fullStr	Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study
title_full_unstemmed	Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study
title_sort	enhancing thermal conductivity and heat transfer performance with nanocellulose-based nanofluids: a comprehensive study
publisher	Springer Science and Business Media Deutschland GmbH
publishDate	2025
_version_	1825816080847732736
score	13.244413

Enhancing Thermal Conductivity and Heat Transfer Performance with Nanocellulose-Based Nanofluids: A Comprehensive Study

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