Email Alert    RSS

Applied Mathematics and Mechanics >

2022 , Vol. 43 >Issue 4: 497 - 506

DOI: https://doi.org/10.1007/s10483-022-2840-7

Articles

Many-body dissipative particle dynamics with energy conservation: temperature-dependent long-term attractive interaction

Expand
  • 1. School of Aerospace Engineering and Applied Mechanics, Tongji University, Shanghai 200092, China;
    2. Institute of Biomechanics and Medical Engineering, AML, Department of Engineering Mechanics, Tsinghua University, Beijing 100084, China;
    3. School of Mechanical and Automotive Engineering, Shanghai University of Engineering Science, Shanghai 201620, China;
    4. Department of Mechanical Engineering, The Hong Kong Polytechnic University, Hung Hom, Kowloon, Hong Kong, China

Received date: 2021-12-10

  Revised date: 2022-02-23

  Online published: 2022-03-29

Supported by

the National Natural Science Foundation of China (Nos. 11872283, 12002242, 11902188, and 12102218), the Shanghai Science and Technology Talent Program (No.19YF1417400), and the China Postdoctoral Science Foundation (No.2020M680525)

Fold

Abstract

Heat and mass transfer during the process of liquid droplet dynamic behaviors has attracted much attention in decades. At mesoscopic scale, numerical simulations of liquid droplets motion, such as impacting, sliding, and coalescence, have been widely studied by using the particle-based method named many-body dissipative particle dynamics (MDPD). However, the detailed information on heat transfer needs further description. This paper develops a modified MDPD with energy conservation (MDPDE) by introducing a temperature-dependent long-term attractive interaction. By fitting or deriving the expressions of the strength of the attractive force, the exponent of the weight function in the dissipative force, and the mesoscopic heat friction coe–cient about temperature, we calculate the viscosity, self-diffusivity, thermal conductivity, and surface tension, and obtain the Schmidt number Sc, the Prandtl number Pr, and the Ohnesorge number Oh for 273 K to 373 K. The simulation data of MDPDE coincide well with the experimental data of water, indicating that our model can be used to simulate the dynamic behaviors of liquid water. Furthermore, we compare the equilibrium contact angle of droplets wetting on solid surfaces with that calculated from three interfacial tensions by MDPDE simulations. The coincident results not only stand for the validation of Young’s equation at mesoscale, but manifest the reliability of our MDPDE model and applicability to the cases with free surfaces. Our model can be extended to study the multiphase flow with complex heat and mass transfer.

Key words: surface tension; Young’s equation; equilibrium contact angle; many-body dissipative particle dynamics with energy conservation (MDPDE)

Cite this article

Jie LI, Kaixuan ZHANG, Chensen LIN, Lanlan XIAO, Yang LIU, Shuo CHEN . Many-body dissipative particle dynamics with energy conservation: temperature-dependent long-term attractive interaction[J]. Applied Mathematics and Mechanics, 2022 , 43(4) : 497 -506 . DOI: 10.1007/s10483-022-2840-7

References

[1] MOEENDARBARY, E., NG, T. Y., and ZANGENEH, M. Dissipative particle dynamics: introduction, methodology and complex fluid applications— a review. International Journal of Applied Mechanics, 1(4), 737-763(2009)
[2] HOOGERBRUGGE, P. and KOELMAN, J. Simulating microscopic hydrodynamic phenomena with dissipative particle dynamics. Europhysics Letters, 19(3), 155(1992)
[3] ESPANOL, P. and WARREN, P. Statistical mechanics of dissipative particle dynamics. Europhysics Letters, 30(4), 191(1995)
[4] ESPANOL, P. Hydrodynamics from dissipative particle dynamics. Physical Review E, 52(2), 1734 (1995)
[5] MARSH, C. A., BACKX, G., and ERNST, M. Static and dynamic properties of dissipative particle dynamics. Physical Review E, 56(2), 1676(1997)
[6] GROOT, R. D. and WARREN, P. B. Dissipative particle dynamics: bridging the gap between atomistic and mesoscopic simulation. The Journal of Chemical Physics, 107(11), 4423-4435(1997)
[7] LI, X., TANG, Y. H., LIANG, H., and KARNIADAKIS,G. Large-scale dissipative particle dynamics simulations of self-assembled amphiphilic systems. Chemical Communications, 50(61), 8306-8308(2014)
[8] QI, X. J., WANG, S., MA, S. H., HAN, K. Q., and LI, X. J. Quantitative prediction of flow dynamics and mechanical retention of surface-altered red blood cells through a splenic slit. Physics of Fluids, 33(5), 051902(2021)
[9] LI, X., PENG, Z., LEI, H., and KARNIADAKIS, G. E. Probing red blood cell mechanics, rheology and dynamics with a two-component multi-scale model. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 372(2021), 20130389(2014)
[10] XIAO, L., LIU, Y., CHEN, S., and FU, B. M. Numerical simulation of a single cell passing through a narrow slit. Biomechanics and Mmodeling in Mechanobiology, 15(6), 1655-1667(2016)
[11] LI, Z., YAZDANI, A., TARTAKOVSKY, A., and KARNIADAKIS, G. E. Transport dissipative particle dynamics model for mesoscopic advection-diffusion-reaction problems. The Journal of Chemical Physics, 143(1), 014101(2015)
[12] ESPANOL, P. and REVENGA, M. Smoothed dissipative particle dynamics. Physical Review E, 67(2), 026705(2003)
[13] LI, G., YE, T., WANG, S., LI, X., and HAQ, R. U. Numerical design of a highly e–cient microfluidic chip for blood plasma separation. Physics of Fluids, 32(3), 031903(2020)
[14] WARREN, P. B. Vapor-liquid coexistence in many-body dissipative particle dynamics. Physical Review E, 68(6), 066702(2003)
[15] ESPANOL, P. Dissipative particle dynamics with energy conservation. Europhysics Letters, 40(6), 631(1997)
[16] LI, Z., HU, G. H., WANG, Z. L., MA, Y. B., and ZHOU, Z. W. Three dimensional flow structures in a moving droplet on substrate: a dissipative particle dynamics study. Physics of Fluids, 25(7), 072103(2013)
[17] AVALOS, J. B. and MACKIE, A. Dissipative particle dynamics with energy conservation. Europhysics Letters, 40(2), 141(1997)
[18] YAMADA, T., JOHANSSON, E. O., SUNDÉN, B., and YUAN, J. L. Dissipative particle dynamics simulations of water droplet flows in a submicron parallel-plate channel for different temperature and surface-wetting conditions. Numerical Heat Transfer, Part A: Applications, 70(6), 595-612(2016)
[19] WANG, L. W., DAI, J. Z., HAO, P. F., HE, F., and ZHANG, X. W. Mesoscopic dynamical model of ice crystal nucleation leading to droplet freezing. ACS Omega, 5(7), 3322-3332(2020)
[20] ZHANG, K., LI, J., CHEN, S., and LIU, Y. Temperature-dependent properties of liquid-vapour coexistence system with many-body dissipative particle dynamics with energy conservation (2020) arXiv:2007.09899v1
[21] LI, Z., TANG, Y. H., LEI, H., CASWELL, B., and KARNIADAKIS, G. E. Energy-conserving dissipative particle dynamics with temperature-dependent properties. Journal of Computational Physics, 265, 113-127(2014)
[22] CHEN, S., LIU, Y., KHOO, B. C., FAN, X. J., and FAN, J. T. Mesoscopic simulation of binary immiscible fluids flow in a square microchannel with hydrophobic surfaces. Computer Modeling in Engineering and Sciences, 19(3), 181-196(2007)
[23] IRVING, J. and KIRKWOOD, J. G. The statistical mechanical theory of transport processes, IV: the equations of hydrodynamics. The Journal of Chemical Physics, 18(6), 817-829(1950)
[24] GHOUFI, A. and MALFREYT, P. Calculation of the surface tension from multibody dissipative particle dynamics and Monte Carlo methods. Physical Review E: Statistical Nonlinear and Soft Matter Physics, 82(1-2), 016706(2010)
[25] SEVENO, D., BLAKE, T. D., and DE CONINCK, J. Young’s equation at the nanoscale. Physical Review Letters, 111(9), 096101(2013)
[26] JIANG, H., MÜLLER-PLATHE, F., and PANAGIOTOPOULOS, A. Z. Contact angles from Young’s equation in molecular dynamics simulations. The Journal of Chemical Physics, 147(8), 084708(2017)
[27] LEROY, F. and MÜLLER-PLATHE, F. Solid-liquid surface free energy of Lennard-Jones liquid on smooth and rough surfaces computed by molecular dynamics using the phantom-wall method. The Journal of Chemical Physics, 133(4), 044110(2010)
[28] BENNETT, C. H. E–cient estimation of free energy differences from Monte Carlo data. Journal of Computational Physics, 22(2), 245-268(1976)
[29] YOUNG, T. An essay on the cohesion of fluids. Philosophical Transactions of the Royal Society of London, 95, 65-87(1805)
[30] HOLZ, M., HEIL, S. R., and SACCO, A. Temperature-dependent self-diffusion coe–cients of water and six selected molecular liquids for calibration in accurate 1H NMR PFG measurements. Physical Chemistry Chemical Physics, 2(20), 4740-4742(2000)
[31] BERGMAN, T. L., LAVINE, A. S., and INCROPERA, F. P. Introduction to Heat Transfer, John Wiley & Sons, New York (2011)
[32] BÖCKH, P. and WETZEL, T. Heat Transfer: Basics and Practice, Springer Science & Business Media, Berlin (2011)
[33] WARREN, P. B. No-go theorem in many-body dissipative particle dynamics. Physical Review E, 87(4), 045303(2013)
Options
Outlines

/

APS Journals | CSTAM Journals | AMS Journals | EMS Journals | ASME Journals
Total visitors:
Copyright © Applied Mathematics and Mechanics (English Edition)
Address:P. O. Box 122, Shanghai University, 99 Shangda Road, Shanghai 200444, China
E-mail: amm@department.shu.edu.cn
Technical support: Beijing Magtech Co.ltd support@magtech.com.cn