纳米结构超疏水表面冷凝现象的三维格子玻尔兹曼方法模拟

胡梦丹; 张庆宇; 孙东科; 朱鸣芳

doi:10.7498/aps.68.20181665

摘要

采用三维多相流格子玻尔兹曼方法(lattice Boltzmann method, LBM), 对纳米结构超疏水表面液滴的冷凝行为进行模拟研究. 通过Laplace定律和光滑表面的本征接触角理论对三维LBM模型进行定量验证. 模拟分析了超疏水表面纳米阵列的几何尺寸和润湿性的局部不均匀性对冷凝液滴形核位置和最终润湿状态的影响规律. 结果表明, 较高的纳米阵列使液滴在纳米结构间隙的上部侧面和底部优先形核长大, 通过采用上下不均匀的间隙可避免液滴在底部形核长大, 而在上部侧面形核的冷凝液滴在生长过程中向上运动, 其润湿状态由Wenzel态转变为Cassie态; 较低的纳米阵列使液滴在纳米结构底部优先形核长大, 液滴的最终润湿状态为Wenzel态; 润湿性不均匀的纳米结构表面使液滴在阵列顶端亲水位置处优先形核长大, 成为Cassie态. 冷凝液滴在不同几何尺寸的纳米结构表面上的最终润湿状态的模拟结果与文献报道的实验结果符合良好. 通过模拟还发现, 冷凝液滴在生长过程中的运动行为与液滴统计平均作用力的变化有关. 本文的LBM模拟再现了三维空间中液滴的形核、长大和润湿状态转变等物理现象.

关键词:

Abstract

Superhydrophobic surfaces resulting from nanoarrays have good performance in anti-condensation. However, the study of droplet nucleation during water vapor condensation is a challenge because of the limitation of observation on a nanoscale, and therefore the fundamental understanding of the influence of geometrical parameters of nanoarrays on the condensation behavior is still less clear. In this work a three-dimensional (3D) multiphase lattice Boltzmann (LB) model is employed to simulate the phenomenon of droplet condensation on the superhydrophobic nanostructured surface. The model validation is carried out through the comparison of the simulations with the results from the Laplace's law and the intrinsic contact angle theory. The LB simulations accord well with the results from Laplace's law. The relative deviation between the simulated intrinsic contact angle and the theoretical value is less than 0.14%, demonstrating the validity of the LB model. Then, the 3D LB model is used to simulate the different preferential nucleation positions and final wetting states of condensate droplets by changing the geometrical parameters, including interpost space, post height and post width, and local wettability of the nanoarrays on superhydrophobic surfaces. It is found that for the nanostructured surfaces patterned with tall posts, the droplets nucleate in the upside interpost space and at the bottom of nanostructures simultaneously. By designing wider and thinner interpost spaces at the downside and upside of the tall nanostructures, respectively, the phenomenon of droplet nucleation at the bottom can be avoided. The simulation results show that the condensate droplets nucleated in the upside interpost space of tall nanostructures migrate upwards during growth, producing a Wenzel-to-Cassie wetting state transition. On the other hand, the condensate droplets nucleated at the bottom of nanostructured surface patterned with short posts produce the Wenzel state. However, by setting non-uniform hydrophilic and hydrophobic regions on the top of the short nanostructures, the condensate droplets are found to nucleate on the hydrophilic top and generate a Cassie state. The simulated final wetting states of condensate droplets on the nanostructures, having various geometrical parameters, compare reasonably well with the experimental observations reported in the literature. It is demonstrated that the migration of condensate droplets is correlated with the evolution of the statistical average force. If the direction of the statistical average force acting on the droplet is upward, the condensate droplets nucleated in the upside interpost space move upward during growth. The 3D LB simulations provide an insight into the physical mechanism of droplet nucleation, growth and wetting state transitions on superhydrophobic nanostructured surfaces.

Keywords:

作者及机构信息

1.
江苏省先进金属材料高技术研究重点实验室, 东南大学材料科学与工程学院, 南京　211189

2.
东南大学机械工程学院, 南京　211189

通信作者: 朱鸣芳, zhumf@seu.edu.cn

基金项目: 国家自然科学基金(批准号: 51371051, 51771118)和江苏省先进金属材料高技术研究重点实验室(批准号: BM2007204)资助的课题.

Authors and contacts

1.
Jiangsu Key Laboratory of Advanced Metallic Materials, School of Materials Science and Engineering, Southeast University, Nanjing 211189, China

2.
School of Mechanical Engineering, Southeast University, Nanjing 211189, China

Corresponding author: Zhu Ming-Fang, zhumf@seu.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 51371051, 51771118) and the Key Laboratory of Advanced Metallic Materials of Jiangsu Province, China (Grant No. BM2007204).

文章全文 : translate this paragraph

参考文献

[1]	Zhang X, Shi F, Niu J, Jiang Y G, Wang Z Q 2008 J. Mater. Chem. 18 621 Google Scholar
[2]	Park K C, Choi H J, Chang C H, Cohen R E, Mckinley G H, Barbastathis G 2012 ACS Nano 6 3789 Google Scholar
[3]	Guo P, Zheng Y M, Wen M X, Song C, Lin Y C, Jiang L 2012 Adv. Mater. 24 2642 Google Scholar
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[5]	柯清平, 李广录, 郝天歌, 何涛, 李雪梅 2010 化学进展 22 284 Ke Q P, Li G L, Hao T G, He T, Li X M 2010 Prog. Chem. 22 284
[6]	郗金明 2008 博士学位论文 (北京: 中国科学院研究生院) Xi J M 2008 Ph. D. Dissertation (Beijing: Graduate University of Chinese Academy of Sciences) (in Chinese)
[7]	刘俊吉, 周亚平, 李松林 2009 物理化学(下卷) (北京: 高等教育出版社) 第487页 Liu J J, Zhou Y P, Li S L 2009 Physical Chemistry (Vol. 2) (Beijing: Higher Education Press) p487 (in Chinese)
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[15]	Narhe R D, Beysens D A 2006 Europhys. Lett. 75 98 Google Scholar
[16]	Rykaczewski K 2012 Langmuir 28 7720 Google Scholar
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[19]	张博 2016 博士学位论文 (北京: 北京化工大学) Zhang B 2016 Ph. D. Dissertation (Beijing: Beijing University of Chemical Technology) (in Chinese)
[20]	Kusumaatmaja H, Leopoldes J, Dupuis A, Yeomans J M 2006 Europhys. Lett. 73 740 Google Scholar
[21]	Kusumaatmaja H, Yeomans J M 2007 Langmuir 23 6019 Google Scholar
[22]	Cui J, Li W Z, Lam W H 2011 Comput. Math. Appl. 61 3678 Google Scholar
[23]	Liu X L, Cheng P, Quan X J 2014 Int. J. Heat Mass Transfer 73 195 Google Scholar
[24]	Zhang Q Y, Sun D K, Zhang Y F, Zhu M F 2014 Langmuir 30 12559 Google Scholar
[25]	Zhang Q Y, Sun D K, Zhang Y F, Zhu M F 2016 Chin. Phys. B 25 066401 Google Scholar
[26]	Shan X W, Chen H D 1993 Phys. Rev. E 47 1815 Google Scholar
[27]	何雅玲, 王勇, 李庆 2009 格子Boltzmann方法的理论及应用 (第一版) (北京: 科学出版社) 第49−52页 He Y L, Wang Y, Li Q 2009 Lattice Boltzmann Method: Theory and Applications (Beijing: Science Press) pp49−52 (in Chinese)
[28]	吴伟 2012 硕士学位论文(南京: 东南大学) Wu W 2012 M. S. Thesis (Nanjing: Southeast University) (in Chinese)
[29]	Sukop M C, Jr Thorne D T 2005 Lattice Boltzmann Modeling-An Introduction for Geoscientists and Engineers (2nd Ed.) (New York: Springer) p89
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施引文献

图 1 D3Q19 LBM模型离散速度示意图^[27]

Fig. 1. Schematic sketch of LBM discrete velocities in the D3Q19 scheme^[27].

下载: 全尺寸图片幻灯片

图 2 模拟的液滴内外压力差与液滴曲率的关系(符号, 模拟值; 直线, 线性拟合)

Fig. 2. Simulated pressure difference between inside and outside of a spherical droplet as a function of droplet curvature (symbols, simulated data; lines, linear fitting).

下载: 全尺寸图片幻灯片

图 3 取G_c = −6.5时模拟的液滴本征接触角随流-固作用系数的变化

Fig. 3. Simulated intrinsic contact angle as a function of the fluid-solid interaction strength at G_c = −6.5.

下载: 全尺寸图片幻灯片

图 4 液滴冷凝的三维模拟区域示意图

Fig. 4. Schematic of the three-dimensional domain for the simulation of droplet condensation.

下载: 全尺寸图片幻灯片

图 5 模拟的液滴在纳米阵列上部侧面和底部同时形核、生长及合并演化过程

Fig. 5. Simulated evolution of droplet nucleation, growth, and coalescence for the droplets that nucleate simultaneously in the upside space and the bottom corners between the posts of nanoarrays.

下载: 全尺寸图片幻灯片

图 6 液滴在纳米阵列上部侧面形核、生长及合并演化过程的LBM模拟结果和实验结果^[17]对比

Fig. 6. Comparison of LBM simulation and experiment^[17] regarding the evolution of droplet nucleation, growth, and coalescence for the droplets that nucleate in the upside space between the posts of nanoarrays.

下载: 全尺寸图片幻灯片

图 7 对应于图6中间隙上部的液相在润湿状态转变阶段所受的统计平均作用力随时间的变化

Fig. 7. Statistical average force of the condensate liquid in the upside space between the posts of nanoarrays in Fig. 6 during wetting state transition as a function of time.

下载: 全尺寸图片幻灯片

图 8 液滴在纳米阵列底部形核、生长及合并演化过程的LBM模拟结果和实验结果^[30]对比

Fig. 8. Comparison of LBM simulation and experiment^[30] regarding the evolution of droplet nucleation, growth, and coalescence for the droplets that nucleate in the bottom corners between the posts of nanoarrays.

下载: 全尺寸图片幻灯片

图 9 模拟的液滴在具有不均匀润湿性的纳米阵列顶端形核、生长及合并演化过程

Fig. 9. Simulated evolution of droplet nucleation, growth, and coalescence on the nanoarrays non-uniformly patterned with hydrophilic and hydrophobic regions on the top of nanoarrays.

下载: 全尺寸图片幻灯片

表 1 取G_c = −6.5时液滴本征接触角设定值与模拟值对比

Table 1. Comparison of intrinsic contact angles between the targeted data and the simulated results (G_c = −6.5).

G_ads	$\theta_{\rm c0} $	$\theta_{\rm c1} $	$\operatorname{Re} {\rm{lative \;error = }}\dfrac{{{\theta _{{\rm{c}}1}} - {\theta _{{\rm{c0}}}}}}{{{\theta _{{\rm{c}}0}}}}$/%
−5.68	0°	0°	0
−3.33	90°	90.13°	0.14
−0.39	180°	180°	0

下载: 导出CSV

[1]	Zhang X, Shi F, Niu J, Jiang Y G, Wang Z Q 2008 J. Mater. Chem. 18 621 Google Scholar
[2]	Park K C, Choi H J, Chang C H, Cohen R E, Mckinley G H, Barbastathis G 2012 ACS Nano 6 3789 Google Scholar
[3]	Guo P, Zheng Y M, Wen M X, Song C, Lin Y C, Jiang L 2012 Adv. Mater. 24 2642 Google Scholar
[4]	Zhang Y F, Yu X Q, Wu H, Wu J 2012 Appl. Surf. Sci. 258 8253 Google Scholar
[5]	柯清平, 李广录, 郝天歌, 何涛, 李雪梅 2010 化学进展 22 284 Ke Q P, Li G L, Hao T G, He T, Li X M 2010 Prog. Chem. 22 284
[6]	郗金明 2008 博士学位论文 (北京: 中国科学院研究生院) Xi J M 2008 Ph. D. Dissertation (Beijing: Graduate University of Chinese Academy of Sciences) (in Chinese)
[7]	刘俊吉, 周亚平, 李松林 2009 物理化学(下卷) (北京: 高等教育出版社) 第487页 Liu J J, Zhou Y P, Li S L 2009 Physical Chemistry (Vol. 2) (Beijing: Higher Education Press) p487 (in Chinese)
[8]	He M, Wang J J, Li H L, Song Y L 2011 Soft Matter 7 3993 Google Scholar
[9]	Enright R, Miljkovic N, Dou N, Nam Y, Wang E N 2013 J. Heat Transfer 135 091304 Google Scholar
[10]	Zhang S N, Huang J Y, Tang Y X, Li S H, Ge M Z, Chen Z, Zhang K Q, Lai Y K 2017 Small 13 1600687 Google Scholar
[11]	Aili A, Ge Q Y, Zhang T J 2017 J. Heat Transfer 139 112401 Google Scholar
[12]	Wenzel R N 1936 J. Ind. Eng. Chem. 28 988 Google Scholar
[13]	Cassie A B D, Baxter S 1944 Trans. Faraday Soc. 40 546 Google Scholar
[14]	Narhe R D, Beysens D A 2004 Phys. Rev. Lett. 93 076103 Google Scholar
[15]	Narhe R D, Beysens D A 2006 Europhys. Lett. 75 98 Google Scholar
[16]	Rykaczewski K 2012 Langmuir 28 7720 Google Scholar
[17]	Lau K K S, Bico J, Teo K B K, Chhowalla M, Amaratunga G A J, Milne W I, McKinley G H, Gleason K K 2003 Nano Lett. 3 1701 Google Scholar
[18]	郭照立, 郑楚光 2009 格子Boltzmann方法的原理和应用 (第一版) (北京: 科学出版社) 第9, 10页 Guo Z L, Zheng C G 2009 Theory and Applications of Lattice Boltzmann Method (Beijing: Science Press) pp9, 10 (in Chinese)
[19]	张博 2016 博士学位论文 (北京: 北京化工大学) Zhang B 2016 Ph. D. Dissertation (Beijing: Beijing University of Chemical Technology) (in Chinese)
[20]	Kusumaatmaja H, Leopoldes J, Dupuis A, Yeomans J M 2006 Europhys. Lett. 73 740 Google Scholar
[21]	Kusumaatmaja H, Yeomans J M 2007 Langmuir 23 6019 Google Scholar
[22]	Cui J, Li W Z, Lam W H 2011 Comput. Math. Appl. 61 3678 Google Scholar
[23]	Liu X L, Cheng P, Quan X J 2014 Int. J. Heat Mass Transfer 73 195 Google Scholar
[24]	Zhang Q Y, Sun D K, Zhang Y F, Zhu M F 2014 Langmuir 30 12559 Google Scholar
[25]	Zhang Q Y, Sun D K, Zhang Y F, Zhu M F 2016 Chin. Phys. B 25 066401 Google Scholar
[26]	Shan X W, Chen H D 1993 Phys. Rev. E 47 1815 Google Scholar
[27]	何雅玲, 王勇, 李庆 2009 格子Boltzmann方法的理论及应用 (第一版) (北京: 科学出版社) 第49−52页 He Y L, Wang Y, Li Q 2009 Lattice Boltzmann Method: Theory and Applications (Beijing: Science Press) pp49−52 (in Chinese)
[28]	吴伟 2012 硕士学位论文(南京: 东南大学) Wu W 2012 M. S. Thesis (Nanjing: Southeast University) (in Chinese)
[29]	Sukop M C, Jr Thorne D T 2005 Lattice Boltzmann Modeling-An Introduction for Geoscientists and Engineers (2nd Ed.) (New York: Springer) p89
[30]	Chen C H, Cai Q, Tsai C, Chen C L, Xiong G, Yu Y, Ren Z 2007 Appl. Phys. Lett. 90 173108 Google Scholar

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