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With the development of higher performance and miniaturization of electronic components, the flow heat transfer of working fluids in nanochannels has received more attention. To elucidate this phenomenon, molecular dynamics simulations are used to simulate the behaviors of fluids within nanochannels at temperatures of 300 K, 325 K, and 350 K. Water serves as a flow medium, with argon substituted for any non-condensable gases. In the flow process, argon atoms aggregate into clusters that are characterized by high potential energy. As the temperature rises, the concomitant increases in the fluid’s potential energy, which leads to the gradual diminution or complete dissipation of these clusters. A minor presence of gas atoms can facilitate fluid movement; however, an excess of argon promotes the formation of larger gaseous clusters in the central region of the channel, thereby impeding fluid flow. Concurrently, the application of heat to the fluid appreciably diminishes the coefficient of flow resistance. The temperature of the fluid in the near-wall region exceeds that of the central area. In the clusters, the atoms exhibit heightened activity, leading to an increase in the average molecular kinetic energy and a concomitant rise in temperature. The inherent hydrogen-bonding structure of water enhances heat transfer within the nanochannels. Argon atoms exert an influence on the number of hydrogen bonds, and rising temperatures disrupts the hydrogen-bond network established by water molecules, ultimately leading to a decrease of the Nusselt number. This investigation offers insights into the heat transfer dynamics of water molecular flow within microchannels under the perturbation of non-condensable gases, thereby furnishing theoretical guidance for enhancing heat transfer within electronic devices.
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Keywords:
- molecular dynamics /
- heat transfer /
- cluster /
- nanochannel
[1] Tang J Q, Liu Y, Huang B L, Xu D Y 2022 Int. J. Therm. Sci. 177 107573Google Scholar
[2] Fathi M, Heyhat M M, Targhi M Z, Bigham S 2023 Int. Commun. Heat Mass Transf. 146 106868Google Scholar
[3] Joseph P, Tabeling P 2005 Phys. Rev. E 71 035303Google Scholar
[4] 苗瑞灿, 张石重, 陈占秀, 杨历 2020 化工进展 39 1641Google Scholar
Miao R C, Zhang S Z, Chen Z X, Yang L 2020 Chem. Ind. Eng. Prog. 39 1641Google Scholar
[5] 梅涛, 陈占秀, 杨历, 王坤, 苗瑞灿 2019 68 094701Google Scholar
Mei T, Chen Z X, Yang L, Wang K, Miao R C 2019 Acta Phys. Sin. 68 094701Google Scholar
[6] Shi L, Hu C Z, Bai M L, Lv J Z 2019 Comput. Mater. Sci. 170 109127Google Scholar
[7] Voronov R S, Papavassiliou D V, Lee L L 2007 Chem. Phys. Lett. 441 273Google Scholar
[8] Zhang C B, Chen Y P 2014 Chem. Eng. Process. 85 203Google Scholar
[9] Priezjev N V 2007 Phys. Rev. E 75 051605Google Scholar
[10] Semiromi D T, Azimian A R 2010 Heat Mass Transfer. 46 791Google Scholar
[11] Markvoort A J, Hilbers P A J, Nedea S V 2005 Phys. Rev. E 71 066702Google Scholar
[12] Zhou W B, Han D M, Xia G D 2022 Appl. Surf. Sci. 591 153155Google Scholar
[13] Bao L Y, Priezjev N V, Hu H B, Luo K 2017 Phys. Rev. E 96 033110Google Scholar
[14] Ge S, Gu Y W, Chen M 2015 Mol. Phys. 113 703Google Scholar
[15] Yao S T, Wang J S, Jin S F, Tan F G, Chen S P 2023 J. Mol. Liq. 371 121105Google Scholar
[16] Alkhwaji A, Elbahloul S, Abdullah M Z, Bakar K F B A 2021 J. Mol. Liq. 324 114703Google Scholar
[17] Hong S N, Choe S H, Jong U G, Pak M S, Yu C J 2019 Fluid Phase Equilib. 487 45Google Scholar
[18] Xi B H, Zhao T, Gao Q W, Wei Z X, Zhao S L 2022 Chem. Eng. Sci. 254 117618Google Scholar
[19] 张石重, 陈占秀, 杨历, 苗瑞灿, 张子剑 2020 化工进展 39 3892Google Scholar
Zhang S Z, Chen Z X, Yang L, Miao R C, Zhang Z J 2020 Chem. Ind. Eng. Prog. 39 3892Google Scholar
[20] Chen L, Wang S Y, Xiang X, Tao W Q 2020 Comput. Mater. Sci. 171 109223Google Scholar
[21] Wu N N, Zeng L C, Fu T, Wang Z H, Lu C 2020 Int. J. Heat Mass Transf. 147 118905Google Scholar
[22] Stukowski A 2010 Modell. Simul. Mat. Sci. Eng. 18 015012Google Scholar
[23] Yao S T, Wang J S, Liu X L 2021 Int. J. Heat Mass Transf. 176 121441Google Scholar
[24] Song Z, Shang X S, Cui Z, Liu Y, Cao Q 2023 Appl. Therm. Eng. 218 119362Google Scholar
[25] 梅涛, 陈占秀, 杨历, 朱洪漫, 苗瑞灿 2020 69 224701Google Scholar
Mei T, Chen Z X, Yang L, Zhu H M, Miao R C 2020 Acta Phys. Sin. 69 224701Google Scholar
[26] Tao J B, Song X Y, Chen W, Zhao S L, Liu H L 2020 Mol. Simul. 46 699Google Scholar
[27] Motlagh M B, Kalteh M 2020 J. Mol. Liq. 318 114028Google Scholar
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图 4 流体的数密度分布 (a) T0 = 300 K, H2O; (b) T0 = 300 K, Ar; (c) T0 = 325 K, H2O; (d) T0 = 325 K, Ar; (e) T0 = 350 K, H2O; (f) T0 = 350 K, Ar
Figure 4. Number density distribution of fluids: (a) T0 = 300 K, H2O; (b) T0 = 300 K, Ar; (c) T0 = 325 K, H2O; (d) T0 = 325 K, Ar; (e) T0 = 350 K, H2O; (f) T0 = 350 K, Ar.
表 1 流道内的粒子数量
Table 1. Number of particles in the channel.
${N_{{{\text{H}}_{2}}{\text{O}}}}$ NAr Case 1 2600 0 Case 2 2200 600 Case 3 2400 400 Case 4 2400 300 Case 5 2400 120 表 2 各原子之间的相互作用势能参数及尺寸参数
Table 2. Interaction potential energy parameters and size parameters of each atom.
原子种类 势能参数 ε/(kcal·mol–1) 尺寸参数 σ/nm O-O 0.1554 0.3166 H-H 0 0 Ar-Ar 0.2392 0.3040 Cu-Cu 0.2379 0.2340 -
[1] Tang J Q, Liu Y, Huang B L, Xu D Y 2022 Int. J. Therm. Sci. 177 107573Google Scholar
[2] Fathi M, Heyhat M M, Targhi M Z, Bigham S 2023 Int. Commun. Heat Mass Transf. 146 106868Google Scholar
[3] Joseph P, Tabeling P 2005 Phys. Rev. E 71 035303Google Scholar
[4] 苗瑞灿, 张石重, 陈占秀, 杨历 2020 化工进展 39 1641Google Scholar
Miao R C, Zhang S Z, Chen Z X, Yang L 2020 Chem. Ind. Eng. Prog. 39 1641Google Scholar
[5] 梅涛, 陈占秀, 杨历, 王坤, 苗瑞灿 2019 68 094701Google Scholar
Mei T, Chen Z X, Yang L, Wang K, Miao R C 2019 Acta Phys. Sin. 68 094701Google Scholar
[6] Shi L, Hu C Z, Bai M L, Lv J Z 2019 Comput. Mater. Sci. 170 109127Google Scholar
[7] Voronov R S, Papavassiliou D V, Lee L L 2007 Chem. Phys. Lett. 441 273Google Scholar
[8] Zhang C B, Chen Y P 2014 Chem. Eng. Process. 85 203Google Scholar
[9] Priezjev N V 2007 Phys. Rev. E 75 051605Google Scholar
[10] Semiromi D T, Azimian A R 2010 Heat Mass Transfer. 46 791Google Scholar
[11] Markvoort A J, Hilbers P A J, Nedea S V 2005 Phys. Rev. E 71 066702Google Scholar
[12] Zhou W B, Han D M, Xia G D 2022 Appl. Surf. Sci. 591 153155Google Scholar
[13] Bao L Y, Priezjev N V, Hu H B, Luo K 2017 Phys. Rev. E 96 033110Google Scholar
[14] Ge S, Gu Y W, Chen M 2015 Mol. Phys. 113 703Google Scholar
[15] Yao S T, Wang J S, Jin S F, Tan F G, Chen S P 2023 J. Mol. Liq. 371 121105Google Scholar
[16] Alkhwaji A, Elbahloul S, Abdullah M Z, Bakar K F B A 2021 J. Mol. Liq. 324 114703Google Scholar
[17] Hong S N, Choe S H, Jong U G, Pak M S, Yu C J 2019 Fluid Phase Equilib. 487 45Google Scholar
[18] Xi B H, Zhao T, Gao Q W, Wei Z X, Zhao S L 2022 Chem. Eng. Sci. 254 117618Google Scholar
[19] 张石重, 陈占秀, 杨历, 苗瑞灿, 张子剑 2020 化工进展 39 3892Google Scholar
Zhang S Z, Chen Z X, Yang L, Miao R C, Zhang Z J 2020 Chem. Ind. Eng. Prog. 39 3892Google Scholar
[20] Chen L, Wang S Y, Xiang X, Tao W Q 2020 Comput. Mater. Sci. 171 109223Google Scholar
[21] Wu N N, Zeng L C, Fu T, Wang Z H, Lu C 2020 Int. J. Heat Mass Transf. 147 118905Google Scholar
[22] Stukowski A 2010 Modell. Simul. Mat. Sci. Eng. 18 015012Google Scholar
[23] Yao S T, Wang J S, Liu X L 2021 Int. J. Heat Mass Transf. 176 121441Google Scholar
[24] Song Z, Shang X S, Cui Z, Liu Y, Cao Q 2023 Appl. Therm. Eng. 218 119362Google Scholar
[25] 梅涛, 陈占秀, 杨历, 朱洪漫, 苗瑞灿 2020 69 224701Google Scholar
Mei T, Chen Z X, Yang L, Zhu H M, Miao R C 2020 Acta Phys. Sin. 69 224701Google Scholar
[26] Tao J B, Song X Y, Chen W, Zhao S L, Liu H L 2020 Mol. Simul. 46 699Google Scholar
[27] Motlagh M B, Kalteh M 2020 J. Mol. Liq. 318 114028Google Scholar
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