Recent advances on the fundamental physical phenomena behind stability, dynamic motion, thermophysical properties, heat transport, applications, and challenges of nanofluids

IF 23.9 1区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Physics Reports Pub Date : 2022-02-02 DOI:10.1016/j.physrep.2021.07.002
Zafar Said , L. Syam Sundar , Arun Kumar Tiwari , Hafiz Muhammad Ali , Mohsen Sheikholeslami , Evangelos Bellos , Hamza Babar
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引用次数: 181

Abstract

In the past decade, nanotechnology’s rapid developments have created quite a lot of prospects for researchers and engineers to check up on. And nanofluids are important consequences of this progression. Nanofluids are created by suspending nanoparticles with average diameters below 100 nm in conventional heat transfer carriers such as water, oil, ethylene glycol, etc. Nanofluids are considered to offer substantial advantages over usual heat transfer fluids. When dispersed in a uniform way and suspended stably in the base fluids, a minimal amount of nanoparticles can significantly improve the thermal properties of host fluids. Present work attempts to address this challenge considering state-of-the-art advances in understanding, discussing, and mitigating problems about nanofluids’ stability. Stable and highly conductive nanofluids are produced by generally, one-step and two-step production methods. Both approaches suffer from problems with the nanoparticles’ agglomeration to be an important one. Thus, numerous numerical models and the principal physical phenomena affecting the stability (fundamental physical principles that govern the interparticle interactions, clustering and deposition kinetics, and colloidal stability theories) have been analyzed. Concerning the particles’ dynamic motion, the significance of different forces in nanofluid in particulate flows such as drag, lift (Magnus and Saffman), Brownian, thermophoretic, Van der Waals, electrostatic double-layer forces are investigated.

Furthermore, an overview of nanofluids’ thermophysical properties, physical models, and heat transfer models is​ included in this work. In order to realize the unexpected discoveries and overcome classical models’ limitations, several researchers have suggested new physical concepts and mechanisms, and they have created new models to enhance the transport properties. This review study includes numerous aspects of the nanofluids’ science by investigating applications, thermal properties and giving critical chronological milestones about the nanofluids’ evolution. Also, the present review discusses in detail various modeling and slip mechanisms for the heat transfer of nanofluids. Potential novel 2D materials as nanofluids have also been discussed and reported. A brief overview of the potential applications utilizing nanofluids has been reviewed, and future research gaps have been reported. Furthermore, recommendations were extracted regarding current scientific gaps and future research directions to cover the physical phenomenon, stability, thermophysical properties, overview of some applications, and the limitations hindering these nanofluids’ deployment. The review is presumed to be valuable for scholars and researchers working in the area of numerical simulations of nanofluids and experimental aspects and help them understand the fundamental physical phenomena taking place during these numerical simulations and experiments and explore the potential of nanofluids both in academia and industry.

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纳米流体的稳定性、动态运动、热物理性质、热传输、应用和挑战背后的基本物理现象的最新进展
在过去的十年里,纳米技术的快速发展为研究人员和工程师创造了相当多的前景。纳米流体是这一进展的重要成果。纳米流体是通过将平均直径小于100纳米的纳米颗粒悬浮在传统的传热载体(如水、油、乙二醇等)中而产生的。纳米流体被认为比通常的传热流体具有实质性的优势。当纳米颗粒均匀分散并稳定悬浮在基础流体中时,少量的纳米颗粒可以显著改善宿主流体的热性能。目前的工作试图解决这一挑战,考虑到了解、讨论和减轻纳米流体稳定性问题的最新进展。稳定和高导电性的纳米流体一般采用一步法和两步法生产。这两种方法都存在纳米颗粒聚集的问题,这是一个重要的问题。因此,许多数值模型和影响稳定性的主要物理现象(控制粒子间相互作用的基本物理原理,聚类和沉积动力学,以及胶体稳定性理论)已经被分析。针对颗粒的动态运动,研究了纳米流体中阻力、升力(Magnus和Saffman)、布朗力、热电泳力、范德华力、静电双层力等作用力对颗粒流动的影响。此外,本文还概述了纳米流体的热物理性质、物理模型和传热模型。为了实现意想不到的发现和克服经典模型的局限性,一些研究人员提出了新的物理概念和机制,并建立了新的模型来增强输运性质。本综述研究包括纳米流体科学的许多方面,通过研究纳米流体的应用、热性质和给出纳米流体发展的关键时间里程碑。此外,本文还详细讨论了纳米流体传热的各种建模和滑移机制。潜在的新型二维材料作为纳米流体也进行了讨论和报道。本文对纳米流体的潜在应用进行了简要综述,并对未来的研究空白进行了报告。此外,针对当前的科学差距和未来的研究方向提出了建议,涵盖了纳米流体的物理现象、稳定性、热物理性质、一些应用概述以及阻碍这些纳米流体部署的限制。本综述对从事纳米流体数值模拟和实验方面工作的学者和研究人员有一定的参考价值,有助于他们了解在这些数值模拟和实验过程中发生的基本物理现象,并探索纳米流体在学术界和工业界的潜力。
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来源期刊
Physics Reports
Physics Reports 物理-物理:综合
CiteScore
56.10
自引率
0.70%
发文量
102
审稿时长
9.1 weeks
期刊介绍: Physics Reports keeps the active physicist up-to-date on developments in a wide range of topics by publishing timely reviews which are more extensive than just literature surveys but normally less than a full monograph. Each report deals with one specific subject and is generally published in a separate volume. These reviews are specialist in nature but contain enough introductory material to make the main points intelligible to a non-specialist. The reader will not only be able to distinguish important developments and trends in physics but will also find a sufficient number of references to the original literature.
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