Simulation of condensation process with different fluids in micro and nanochannels to investigate the wall material, curvature of the channel, and electric and magnetic fields using the molecular dynamics approach

IF 6.4 2区工程技术 Q1 MECHANICS

International Communications in Heat and Mass Transfer Pub Date : 2025-04-16 DOI:10.1016/j.icheatmasstransfer.2025.108951

Zekun Liu , Mengxia Wang , Nafiseh Emami , Soheil Salahshour , Riadh Marzouki

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Abstract

Nowadays, computer simulations are a suitable tool for understanding physical phenomena. This paper examined the condensation process of various fluids in micro/nanochannels (MCs/NCs) using molecular dynamics simulations (MDS). The present study examined the condensation time in MCs and NCs across different base fluid types, atomic materials, the number of atomic curvatures (NAC), and the intensities of electric field (EF) and magnetic field (MF). The results reveal that the time required for phase change (condensation) in the helium (He) fluid-structure was less in MCs (2.91 ns) and NCs (2.72 ns) compared to other samples. Changing the atomic materials of MCs and NCs (copper (Cu), platinum (Pt), and Cu/Pt) showed that Pt reduced the condensation times to 2.62 ns for MCs and 2.58 ns for NCs. To enhance atomic interactions in the simulated MCs and NCs, the NAC was modeled at 1, 2, and 3. Increasing the NAC in MCs and NCs decreased the condensation times from 2.91 ns and 2.72 ns to 2.62 ns and 2.58 ns, respectively. The results indicate that condensation time decreases as NAC increases. Increasing the intensities of EF and MF enhanced a fluid's atomic mobility and kinetic energy (KE). Applying an EF with magnitudes of 0, 1, 2, and 5 V/m increased the condensation times of MCs and NCs from 2.91 ns and 2.72 ns to 3.39 ns and 3.36 ns, respectively. Additionally, changing the intensity of MF altered the phase change times in MCs and NCs to 3.17 ns and 3.15 ns, respectively.

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用分子动力学方法模拟微纳米通道中不同流体的凝结过程，研究通道壁材料、通道曲率以及电场和磁场

如今，计算机模拟是理解物理现象的合适工具。本文利用分子动力学模拟（MDS）研究了不同流体在微纳米通道（MCs/NCs）中的冷凝过程。本研究考察了不同基流体类型、原子材料、原子曲率数（NAC）和电场强度（EF）和磁场强度（MF）下MCs和nc的凝结时间。结果表明，与其他样品相比，MCs和nc样品中He流体结构的相变（冷凝）所需时间较短，分别为2.91 ns和2.72 ns。改变MCs和nc的原子材料（铜（Cu）、铂（Pt）和Cu/Pt）表明，Pt使MCs的缩聚时间缩短至2.62 ns， nc的缩聚时间缩短至2.58 ns。为了增强模拟mc和nc中的原子相互作用，NAC在1、2和3处建模。增加MCs和NCs的NAC，凝结时间分别从2.91 ns和2.72 ns降低到2.62 ns和2.58 ns。结果表明，随着NAC的增加，凝结时间缩短。增大EF和MF的强度可以提高流体的原子迁移率和动能。施加0、1、2和5 V/m的EF，使MCs和nc的凝结时间分别从2.91 ns和2.72 ns增加到3.39 ns和3.36 ns。此外，改变MF强度可使MCs和nc的相变时间分别达到3.17 ns和3.15 ns。

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来源期刊

International Communications in Heat and Mass Transfer 工程技术-力学

CiteScore

11.00

自引率

10.00%

发文量

648

审稿时长

32 days

期刊介绍： International Communications in Heat and Mass Transfer serves as a world forum for the rapid dissemination of new ideas, new measurement techniques, preliminary findings of ongoing investigations, discussions, and criticisms in the field of heat and mass transfer. Two types of manuscript will be considered for publication: communications (short reports of new work or discussions of work which has already been published) and summaries (abstracts of reports, theses or manuscripts which are too long for publication in full). Together with its companion publication, International Journal of Heat and Mass Transfer, with which it shares the same Board of Editors, this journal is read by research workers and engineers throughout the world.