受限于对称性破缺狭缝间氢键流体的界面性质

doi:10.3969/j.issn.1000-1565.2014.06.008

河北大学学报(自然科学版) ›› 2014, Vol. 34 ›› Issue (6): 603-609.DOI: 10.3969/j.issn.1000-1565.2014.06.008

受限于对称性破缺狭缝间氢键流体的界面性质

刘晓雨¹,张雅楠¹,张泽坤¹,顾芳²

1.河北大学化学与环境科学学院,河北保定,071002； 2.河北大学化学与环境科学学院,河北保定071002;华北电力大学环境科学与工程学院,河北保定071003

出版日期:2014-11-25 发布日期:2014-11-25
基金资助:
国家自然科学基金资助项目，河北省自然科学基金资助项目，河北省青年拔尖人才项目，河北省高等学校科学技术研究项目，河北大学大学生创新创业训练计划项目

Interfacial properties of hydrogen bonding fluid in a slit pore with broken symmetry

LIU Xiaoyu¹,ZHANG Yanan¹,ZHANG Zekun¹,GU Fang²

Online:2014-11-25 Published:2014-11-25

摘要/Abstract

摘要： 利用经典流体的密度泛函理论并结合改进的基本度量理论研究了受限于对称性破缺狭缝间氢键流体的界面性质.首先,根据氢键流体在狭缝间的吸附-脱附等温线以及相应的巨势等温线获得不同条件下氢键流体的界面张力.在此基础上,集中讨论了对称性破缺程度、氢键键能以及狭缝间距等因素对氢键流体界面特征的影响.结果表明:流体的界面性质与这些因素密切相关,研究结果可为进一步揭示对称性破缺条件下流体的相平衡及界面特征提供可能的理论线索.

关键词: 氢键流体, 对称性破缺, 界面张力, 密度泛函理论

Key words: hydrogen bonding fluid, broken symmetry, interfacial tension, density functional theory

中图分类号:

O631.1 O642.4

刘晓雨,张雅楠,张泽坤,顾芳. 受限于对称性破缺狭缝间氢键流体的界面性质[J]. 河北大学学报(自然科学版), 2014, 34(6): 603-609.

LIU Xiaoyu,ZHANG Yanan,ZHANG Zekun,GU Fang. Interfacial properties of hydrogen bonding fluid in a slit pore with broken symmetry[J]. Journal of Hebei University (Natural Science Edition), 2014, 34(6): 603-609.

参考文献

[1] 王海军. AaDd型氢键流体的统计理论(Ⅰ):几何相变 [J]. 中国科学B辑 2006.doi:10.3321/j.issn:1006-9240.2006.03.004
[2] DORE J C, TEIXEIRA J. Hydorgen-bonded liquids [M]. Dordrecht:Kulumer Academic Publishers 1991.
[3] DUNNE L J, MANOS G. Adsorption and phase behaviour in nanochannels and nanotubes [M]. New York:Springer-Verlag 2010.
[4] J(O)ZSEF T. Adsorption:Theory, modeling and analysis [M]. New York:Marcel Dekker, Inc 2002.
[5] Malo BM., Patrykiejew A., Sokolowski S., Pizio O.. Adsorption and phase transitions in a two-site associating Lennard-Jones fluid confined to energetically heterogeneous slit-like pores; application of the density functional method [J]. Journal of Physics. Condensed Matter 2001, 7(7).
[6] LI Zhidong, CAO Dapeng, WU Jianzhong. Layering, condensation, and evaporation of short chains in narrow slit pores [J]. Journal of Chemical Physics 2005, 122.
[7] FU Dong, LI Xiaosen. Phase equilibria and plate-fluid interfacial tensions for associating hard sphere fluids confined in silt pores [J]. Journal of Chemical Physics 2006, 125.
[8] PENG Bo, YU Yangxin. A density functional theory with a mean-field weight function:Applications to surface tension, adsorption, and phase transition of a Lennard-Jones fluid in a slit-like pore [J]. Journal of Physical Chemistry B 2008, 112.
[9] 李小森, 吴慧杰, Li Xiaosen, Wu Huijie. 缔合Lennard-Jones流体在纳米缝隙中的界面性质研究 [J]. 化学学报 2011.
[10] Rasmussen, Christopher J., Vishnyakov, Aleksey, Thommes, Matthias, Smarsly, Bernd M., Kleitz, Freddy, Neimark, Alexander V.. Cavitation in Metastable Liquid Nitrogen Confined to Nanoscale Pores [J]. Langmuir: The ACS Journal of Surfaces and Colloids 2010, 12(12).
[11] 顾芳, 王海军, 齐子玉. AaDd型氢键流体的统计理论（Ⅳ）：胶体粒子间的耗尽势 [J]. 2012.doi:10.1007/s11426-012-4608-8
[12] EVANS R. The nature of the liquid-vapour interface and other topics in the statistical mechanics of non-uniform, classical fluids [J]. Advances in Physics 1979, 28.
[13] RAMAKRISHNAN T V, YUSSOUFF M. First-principles order-parameter theory of freezing [J]. Physical Review B:Condensed Matter 1979, 19.
[14] ROSENFELD Y. Free-energy model for the inhomogeneous hard-sphere fluid mixture and density-functional theory of freezing [J]. Physical Review Letters 1989, 63.
[15] Yang-Xin Yu, Jianzhong Wu. Structures of hard-sphere fluids from a modified fundamental-measure theory [J]. The Journal of Chemical Physics 2002, 22(22).
[16] Roth R., Evans R., Lang A., Kahl G.. Fundamental measure theory for hard-sphere mixtures revisited: the White Bear version [J]. Journal of Physics. Condensed Matter 2002, 46(46).
[17] Y. Rosenfeld, M. Schmidt, H. Lowen, P. Tarazona. Fundamental-measure free-energy density functional for hard spheres: Dimensional crossover and freezing [J]. Physical review.E.Statistical physics, plasmas, fluids, and related interdisciplinary topics 1997, 4(4).
[18] Yang-Xin Yu, Jiangzhou Wu, Yu-Xuan Xin. Structures and correlation functions of multicomponent and polydisperse hard-sphere mixtures from a density functional theory [J]. The Journal of Chemical Physics 2004, 3(3).
[19] Yang-Xin Yu, JiangzhongWu. A fundamental-measure theory for inhomogeneous associating fluids [J]. The Journal of Chemical Physics 2002, 16(16).
[20] WEEKS JD, CHANDLER D, ANDERSON HC. Role of repulsive forces in determining the equilibrium structure of simple liquids [J]. Journal of Chemical Physics 1971, 54.
[21] 顾芳, 王海军, 付东. AaDd型氢键流体的统计理论（Ⅴ）：球形微腔中的相平衡 [J]. 2013.doi:10.1360/032012-23
[22] Chad J.Segura, Walter G.Chapman, Keshawa P.Shukla. Associating fluids with four bonding sites against a hard wall: density functional theory [J]. Molecular physics 1997, 5(5).

受限于对称性破缺狭缝间氢键流体的界面性质

Interfacial properties of hydrogen bonding fluid in a slit pore with broken symmetry

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