Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by
Crossref.
Muradoglu, Metin
and
Tryggvason, Gretar
2014.
Simulations of soluble surfactants in 3D multiphase flow.
Journal of Computational Physics,
Vol. 274,
Issue. ,
p.
737.
TRYGGVASON, Gretar
and
LU, Jiacai
2015.
Direct numerical simulations of bubbly flows.
Mechanical Engineering Reviews,
Vol. 2,
Issue. 2,
p.
15-00220.
Tryggvason, Grétar
and
Lu, Jiacai
2015.
Direct Numerical Simulations of Flows with Phase Change.
Procedia IUTAM,
Vol. 15,
Issue. ,
p.
2.
Ma, Ming
Lu, Jiacai
and
Tryggvason, Gretar
2015.
Using statistical learning to close two-fluid multiphase flow equations for a simple bubbly system.
Physics of Fluids,
Vol. 27,
Issue. 9,
Santarelli, C.
and
Fröhlich, J.
2015.
Direct Numerical Simulations of spherical bubbles in vertical turbulent channel flow.
International Journal of Multiphase Flow,
Vol. 75,
Issue. ,
p.
174.
Dabiri, Sadegh
and
Tryggvason, Gretar
2015.
Heat transfer in turbulent bubbly flow in vertical channels.
Chemical Engineering Science,
Vol. 122,
Issue. ,
p.
106.
Santarelli, C.
Roussel, J.
and
Fröhlich, J.
2016.
Budget analysis of the turbulent kinetic energy for bubbly flow in a vertical channel.
Chemical Engineering Science,
Vol. 141,
Issue. ,
p.
46.
Santarelli, C.
and
Fröhlich, J.
2016.
Direct Numerical Simulations of spherical bubbles in vertical turbulent channel flow. Influence of bubble size and bidispersity.
International Journal of Multiphase Flow,
Vol. 81,
Issue. ,
p.
27.
Fu, Yucheng
and
Liu, Yang
2016.
Development of a robust image processing technique for bubbly flow measurement in a narrow rectangular channel.
International Journal of Multiphase Flow,
Vol. 84,
Issue. ,
p.
217.
Besagni, Giorgio
and
Inzoli, Fabio
2016.
Comprehensive experimental investigation of counter-current bubble column hydrodynamics: Holdup, flow regime transition, bubble size distributions and local flow properties.
Chemical Engineering Science,
Vol. 146,
Issue. ,
p.
259.
Besagni, Giorgio
Brazzale, Pietro
Fiocca, Alberto
and
Inzoli, Fabio
2016.
Estimation of bubble size distributions and shapes in two-phase bubble column using image analysis and optical probes.
Flow Measurement and Instrumentation,
Vol. 52,
Issue. ,
p.
190.
Lakehal, D.
Métrailler, D.
and
Reboux, S.
2017.
Turbulent water flow in a channel at Re
τ = 400 laden with 0.25 mm diameter air-bubbles clustered near the wall.
Physics of Fluids,
Vol. 29,
Issue. 6,
Besagni, Giorgio
Inzoli, Fabio
De Guido, Giorgia
and
Pellegrini, Laura Annamaria
2017.
The dual effect of viscosity on bubble column hydrodynamics.
Chemical Engineering Science,
Vol. 158,
Issue. ,
p.
509.
Besagni, Giorgio
Inzoli, Fabio
Ziegenhein, Thomas
and
Lucas, Dirk
2017.
Computational Fluid-Dynamic modeling of the pseudo-homogeneous flow regime in large-scale bubble columns.
Chemical Engineering Science,
Vol. 160,
Issue. ,
p.
144.
Lu, Jiacai
Muradoglu, Metin
and
Tryggvason, Gretar
2017.
Effect of insoluble surfactant on turbulent bubbly flows in vertical channels.
International Journal of Multiphase Flow,
Vol. 95,
Issue. ,
p.
135.
Besagni, Giorgio
and
Inzoli, Fabio
2017.
The effect of liquid phase properties on bubble column fluid dynamics: Gas holdup, flow regime transition, bubble size distributions and shapes, interfacial areas and foaming phenomena.
Chemical Engineering Science,
Vol. 170,
Issue. ,
p.
270.
Ma, Tian
Santarelli, Claudio
Ziegenhein, Thomas
Lucas, Dirk
and
Fröhlich, Jochen
2017.
Direct numerical simulation–based Reynolds-averaged closure for bubble-induced turbulence.
Physical Review Fluids,
Vol. 2,
Issue. 3,
Loisy, Aurore
and
Naso, Aurore
2017.
Interaction between a large buoyant bubble and turbulence.
Physical Review Fluids,
Vol. 2,
Issue. 1,
Métrailler, D.
Reboux, S.
and
Lakehal, D.
2017.
Near-wall turbulence-bubbles interactions in a channel flow at Re τ = 400: A DNS investigation.
Nuclear Engineering and Design,
Vol. 321,
Issue. ,
p.
180.
Magolan, Ben
Baglietto, Emilio
Brown, Cameron
Bolotnov, Igor A.
Tryggvason, Gretar
and
Lu, Jiacai
2017.
Multiphase turbulence mechanisms identification from consistent analysis of direct numerical simulation data.
Nuclear Engineering and Technology,
Vol. 49,
Issue. 6,
p.
1318.