A discrete droplet method for modelling thin film flows

Bharadwaj, Anand S.; Kuhnert, Joerg; BORDAS, Stéphane; SUCHDE, Pratik

doi:10.1016/j.apm.2022.08.001

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A discrete droplet method for modelling thin film flows

Bharadwaj, Anand S.; Kuhnert, Joerg; BORDAS, Stéphane et al.

2022 • In Applied Mathematical Modelling, 112, p. 486--504

Peer Reviewed verified by ORBi

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https://hdl.handle.net/10993/53438

DOI
10.1016/j.apm.2022.08.001

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Disciplines :

Mechanical engineering
Engineering, computing & technology: Multidisciplinary, general & others
Aerospace & aeronautics engineering

Author, co-author :

Bharadwaj, Anand S.

Kuhnert, Joerg

BORDAS, Stéphane ; University of Luxembourg > Faculty of Science, Technology and Medicine (FSTM) > Department of Engineering (DoE)

SUCHDE, Pratik ; University of Luxembourg > Faculty of Science, Technology and Medicine (FSTM) > Department of Engineering (DoE)

External co-authors :

yes

Language :

English

Title :

A discrete droplet method for modelling thin film flows

Publication date :

2022

Journal title :

Applied Mathematical Modelling

ISSN :

0307-904X

eISSN :

1872-8480

Publisher :

Elsevier

Volume :

112

Pages :

486--504

Peer reviewed :

Peer Reviewed verified by ORBi

European Projects :

H2020 - 892761 - SURFING - Flow on thin fluid sheets

Funders :

CE - Commission Européenne
Union Européenne

Available on ORBilu :

since 02 January 2023

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Bibliography

Luo, J., Wen, S., Huang, P., Thin film lubrication. part i. study on the transition between ehl and thin film lubrication using a relative optical interference intensity technique. Wear 194:1–2 (1996), 107–115.
Overhoff, K., Johnston, K., Tam, J., Engstrom, J., Williams III, R., Use of thin film freezing to enable drug delivery: a review. J. Drug Deliv. Sci. Technol. 19:2 (2009), 89–98.
Jiang, R., Pawliszyn, J., Thin-film microextraction offers another geometry for solid-phase microextraction. TrAC, Trends Anal. Chem. 39 (2012), 245–253.
Lee, D., Condrate, R., Ftir spectral characterization of thin film coatings of oleic acid on glasses: i. coatings on glasses from ethyl alcohol. J. Mater. Sci. 34:1 (1999), 139–146.
Tvingstedt, K., Dal Zilio, S., Inganäs, O., Tormen, M., Trapping light with micro lenses in thin film organic photovoltaic cells. Opt. Express 16:26 (2008), 21608–21615.
O'Hara, J.F., Withayachumnankul, W., Al-Naib, I., A review on thin-film sensing with terahertz waves. J. Infrared Millimeter Terahertz Waves 33:3 (2012), 245–291.
Rabiei, E., Haberlandt, U., Sester, M., Fitzner, D., Rainfall estimation using moving cars as rain gauges–laboratory experiments. Hydrol. Earth Syst. Sci. 17:11 (2013), 4701–4712.
Benney, Long waves on liquid films. J. Math. Phys. 45:1–4 (1966), 150–155.
Ng, C.-O., Mei, C.C., Roll waves on a shallow layer of mud modelled as a power-law fluid. J. Fluid Mech. 263 (1994), 151–184.
Atherton, R., Homsy, G., On the derivation of evolution equations for interfacial waves. Chem. Eng. Commun. 2:2 (1976), 57–77.
O'Brien, S.B., Schwartz, L.W., Thin Film Flows: Theory and Modeling. Encyclopedia of Surface and Colloid Science, Third Edition, 2015, CRC Press, 7377–7390.
Myers, T.G., Thin films with high surface tension. SIAM Rev. 40:3 (1998), 441–462.
Danov, K.D., Alleborn, N., Raszillier, H., Durst, F., The stability of evaporating thin liquid films in the presence of surfactant. i. lubrication approximation and linear analysis. Phys. Fluids 10:1 (1998), 131–143.
Bertozzi, A.L., Pugh, M., The lubrication approximation for thin viscous films: regularity and long-time behavior of weak solutions. Commun. Pure Appl. Math. 49:2 (1996), 85–123.
Barra, V., Afkhami, S., Kondic, L., Interfacial dynamics of thin viscoelastic films and drops. J. Nonnewton Fluid Mech. 237 (2016), 26–38.
Schwartz, L., Weidner, D., Modeling of coating flows on curved surfaces. J. Eng. Math. 29:1 (1995), 91–103.
Fernández-Nieto, E.D., Noble, P., Vila, J.-P., Shallow water equations for non-newtonian fluids. J. Nonnewton Fluid Mech. 165:13–14 (2010), 712–732.
Noble, P., Vila, J.-P., Thin power-law film flow down an inclined plane: consistent shallow-water models and stability under large-scale perturbations. J. Fluid Mech. 735 (2013), 29–60.
Chun, S., Eskilsson, C., Method of moving frames to solve the shallow water equations on arbitrary rotating curved surfaces. J. Comput. Phys. 333 (2017), 1–23.
Ren, B., Yuan, T., Li, C., Xu, K., Hu, S.-M., Real-time high-fidelity surface flow simulation. IEEE Trans. Vis. Comput. Graph 24:8 (2017), 2411–2423.
Fang, S., Nash embedding, shape operator and navier-stokes equation on a riemannian manifold. Acta Math. Appl. Sinica English Ser. 36:2 (2020), 237–252.
Samavaki, M., Tuomela, J., Navier–stokes equations on riemannian manifolds. J. Geom. Phys., 148, 2020, 103543.
Chan, C.H., Czubak, M., Disconzi, M.M., The formulation of the navier–stokes equations on riemannian manifolds. J. Geom. Phys. 121 (2017), 335–346.
Zhao, Y., Tan, H.H., Zhang, B., A high-resolution characteristics-based implicit dual time-stepping vof method for free surface flow simulation on unstructured grids. J. Comput. Phys. 183:1 (2002), 233–273.
Nguyen, V.-T., Park, W.-G., A free surface flow solver for complex three-dimensional water impact problems based on the vof method. Int. J. Numer. Methods Fluids 82:1 (2016), 3–34.
Issakhov, A., Zhandaulet, Y., Nogaeva, A., Numerical simulation of dam break flow for various forms of the obstacle by vof method. Int. J. Multiphase Flow 109 (2018), 191–206.
Larmaei, M.M., Mahdi, T.-F., Simulation of shallow water waves using vof method. J. Hydro-Environ. Res. 3:4 (2010), 208–214.
Fries, T.-P., Higher-order surface fem for incompressible navier-stokes flows on manifolds. Int. J. Numer. Methods Fluids 88:2 (2018), 55–78.
Jankuhn, T., Olshanskii, M.A., Reusken, A., Incompressible fluid problems on embedded surfaces: modeling and variational formulations. Interfaces Free Boundaries 20:3 (2018), 353–377.
Gross, B.J., Atzberger, P.J., Hydrodynamic flows on curved surfaces: spectral numerical methods for radial manifold shapes. J. Comput. Phys. 371 (2018), 663–689.
Xu, X., Dey, M., Qiu, M., Feng, J.J., Modeling of van der waals force with smoothed particle hydrodynamics: application to the rupture of thin liquid films. Appl. Math. Model. 83 (2020), 719–735.
Solenthaler, B., Bucher, P., Chentanez, N., Müller, M., Gross, M., Sph based shallow water. Simulation, 2011.
Chang, T.-J., Kao, H.-M., Chang, K.-H., Hsu, M.-H., Numerical simulation of shallow-water dam break flows in open channels using smoothed particle hydrodynamics. J. Hydrol. (Amst.) 408:1–2 (2011), 78–90.
Wang, M., Deng, Y., Kong, X., Prasad, A.H., Xiong, S., Zhu, B., Thin-film smoothed particle hydrodynamics fluid. ACM Trans. Graphic. (TOG) 40:4 (2021), 1–16.
Kordilla, J., Tartakovsky, A.M., Geyer, T., A smoothed particle hydrodynamics model for droplet and film flow on smooth and rough fracture surfaces. Adv. Water Resour. 59 (2013), 1–14.
Härdi, S., Schreiner, M., Janoske, U., Enhancing smoothed particle hydrodynamics for shallow water equations on small scales by using the finite particle method. Comput. Methods Appl. Mech. Eng. 344 (2019), 360–375.
Härdi, S., Schreiner, M., Janoske, U., Simulating thin film flow using the shallow water equations and smoothed particle hydrodynamics. Comput. Methods Appl. Mech. Eng., 358, 2020, 112639.
Suchde, P., Kuhnert, J., A fully lagrangian meshfree framework for pdes on evolving surfaces. J. Comput. Phys. 395 (2019), 38–59.
Suchde, P., Kuhnert, J., A meshfree generalized finite difference method for surface pdes. Comput. Math. Appl. 78:8 (2019), 2789–2805.
Suchde, P., A meshfree lagrangian method for flow on manifolds. Int. J. Numer. Methods Fluids 93:6 (2021), 1871–1894.
Lu, L., Gopalan, B., Benyahia, S., Assessment of different discrete particle methods ability to predict gas-particle flow in a small-scale fluidized bed. Ind. Eng. Chem. Res. 56:27 (2017), 7865–7876.
Zahari, N., Zawawi, M., Sidek, L., Mohamad, D., Itam, Z., Ramli, M., Syamsir, A., Abas, A., Rashid, M., Introduction of discrete phase model (dpm) in fluid flow: a review. AIP Conference Proceedings, volume 2030, 2018, AIP Publishing LLC, 020234.
Longest, P.W., Xi, J., Evaluation of continuous and discrete phase models for simulating submicrometer aerosol transport and deposition. Comput. Fluid Dyn. Heat Transf.: Emerg. Top., 23, 2011, 425.
Liu, G.-R., Liu, M.B., Smoothed particle hydrodynamics: A meshfree particle method. 2003, World scientific.
Domínguez, J., Crespo, A., Gómez-Gesteira, M., Marongiu, J., Neighbour lists in smoothed particle hydrodynamics. Int. J. Numer. Methods Fluids 67:12 (2011), 2026–2042.
Drumm, C., Tiwari, S., Kuhnert, J., Bart, H.-J., Finite pointset method for simulation of the liquid–liquid flow field in an extractor. Comput. Chem. Eng. 32:12 (2008), 2946–2957.
Suchde, P., Kuhnert, J., Point cloud movement for fully lagrangian meshfree methods. J. Comput. Appl. Math. 340 (2018), 89–100.
LeVeque, R.J., et al. Finite volume methods for hyperbolic problems. volume 31, 2002, Cambridge university press.
Saucedo-Zendejo, F.R., Reséndiz-Flores, E.O., A new approach for the numerical simulation of free surface incompressible flows using a meshfree method. Comput. Methods Appl. Mech. Eng. 324 (2017), 619–639.
Basic, J., Degiuli, N., Blagojevic, B., Ban, D., Lagrangian differencing dynamics for incompressible flows. J. Comput. Phys., 2022, 111198.
Mingham, C., Causon, D., High-resolution finite-volume method for shallow water flows. J. Hydraul. Eng. 124:6 (1998), 605–614.