Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by Crossref.
Joseph, Daniel D.
2006.
Potential flow of viscous fluids: Historical notes.
International Journal of Multiphase Flow,
Vol. 32,
Issue. 3,
p.
285.
Joseph, Daniel D.
2006.
Helmholtz decomposition coupling rotational to irrotational flow of a viscous fluid.
Proceedings of the National Academy of Sciences,
Vol. 103,
Issue. 39,
p.
14272.
Padrino, J. C.
and
Joseph, D. D.
2007.
Correction of Lamb’s dissipation calculation for the effects of viscosity on capillary-gravity waves.
Physics of Fluids,
Vol. 19,
Issue. 8,
Dias, F.
Dyachenko, A.I.
and
Zakharov, V.E.
2008.
Theory of weakly damped free-surface flows: A new formulation based on potential flow solutions.
Physics Letters A,
Vol. 372,
Issue. 8,
p.
1297.
Padrino, J.C.
Funada, T.
and
Joseph, D.D.
2008.
Purely irrotational theories for the viscous effects on the oscillations of drops and bubbles.
International Journal of Multiphase Flow,
Vol. 34,
Issue. 1,
p.
61.
RAVAL, ASHISH
WEN, XIANYUN
and
SMITH, MICHAEL H.
2009.
Numerical simulation of viscous, nonlinear and progressive water waves.
Journal of Fluid Mechanics,
Vol. 637,
Issue. ,
p.
443.
Joshi, Amey S.
Radhakrishna, M. C.
and
Rudraiah, N.
2011.
Kelvin-Helmholtz instability in viscoelastic fluids in presence of electro-magnetic fields.
Physics of Fluids,
Vol. 23,
Issue. 9,
p.
094107.
Turner, M.R.
2016.
Liquid sloshing in a horizontally forced vessel with bottom topography.
Journal of Fluids and Structures,
Vol. 64,
Issue. ,
p.
1.
Hsieh, Chih-Min
Sau, Amalendu
Hwang, Robert R.
and
Yang, W. C.
2016.
Nonlinear interaction and wave breaking with a submerged porous structure.
Physics of Fluids,
Vol. 28,
Issue. 12,
Manmi, Kawa
and
Wang, Qianxi
2017.
Acoustic microbubble dynamics with viscous effects.
Ultrasonics Sonochemistry,
Vol. 36,
Issue. ,
p.
427.
Funada, Toshio
2017.
Encyclopedia of Maritime and Offshore Engineering.
p.
1.
Armaroli, Andrea
Eeltink, Debbie
Brunetti, Maura
and
Kasparian, Jérôme
2018.
Viscous damping of gravity-capillary waves: Dispersion relations and nonlinear corrections.
Physical Review Fluids,
Vol. 3,
Issue. 12,
Feng, X.
Chen, X.B.
and
Dias, F.
2018.
A potential flow model with viscous dissipation based on a modified boundary element method.
Engineering Analysis with Boundary Elements,
Vol. 97,
Issue. ,
p.
1.
Granero-Belinchón, Rafael
and
Scrobogna, Stefano
2019.
Models for Damped Water Waves.
SIAM Journal on Applied Mathematics,
Vol. 79,
Issue. 6,
p.
2530.
Eeltink, D.
Armaroli, A.
Brunetti, M.
and
Kasparian, J.
2020.
Reconciling different formulations of viscous water waves and their mass conservation.
Wave Motion,
Vol. 97,
Issue. ,
p.
102610.
Granero-Belinchón, Rafael
and
Scrobogna, Stefano
2021.
Global well-posedness and decay for viscous water wave models.
Physics of Fluids,
Vol. 33,
Issue. 10,
Wang, Qianxi
Liu, Wenke
Corbett, Callan
and
Smith, Warren R.
2022.
Microbubble dynamics in a viscous compressible liquid subject to ultrasound.
Physics of Fluids,
Vol. 34,
Issue. 1,
Sun, Hao
Zhao, Yang
Liu, Zhongbo
and
Liu, Yong
2023.
A two-layer viscous Boussinesq-type model for surface waves: Derivation, analysis, numerical implementation, and verification.
Physics of Fluids,
Vol. 35,
Issue. 3,
Brudvik-Lindner, Larkspur
Mitsotakis, Dimitrios
and
Tzavaras, Athanasios E
2023.
Oscillatory and regularized shock waves for a dissipative Peregrine–Boussinesq system.
IMA Journal of Applied Mathematics,
Vol. 88,
Issue. 4,
p.
602.
Turner, M. R.
2024.
Dynamic sloshing in a rectangular vessel with porous baffles.
Journal of Engineering Mathematics,
Vol. 144,
Issue. 1,