Discontinuous fluids

Jeong Mo Hong; Chang Hun Kim

doi:10.1145/1073204.1073283

Discontinuous fluids

Jeong Mo Hong, Chang Hun Kim

Department of Computer Science and Engineering

Research output: Contribution to journal › Conference article › peer-review

145 Citations (Scopus)

Abstract

At interfaces between different fluids, properties such as density, viscosity, and molecular cohesion are discontinuous. To animate small-scale details of incompressible viscous multi-phase fluids realistically, we focus on the discontinuities in the state variables that express these properties. Surface tension of both free and bubble surfaces is modeled using the jump condition in the pressure field; and discontinuities in the velocity gradient field, driven by viscosity differences, are also considered. To obtain derivatives of the pressure and velocity fields with sub-grid accuracy, they are extrapolated across interfaces using continuous variables based on physical properties. The numerical methods that we present are easy to implement and do not impact the performance of existing solvers. Small-scale fluid motions, such as capillary instability, breakup of liquid sheets, and bubbly water can all be successfully animated.

Original language	English
Pages (from-to)	915-920
Number of pages	6
Journal	ACM Transactions on Graphics
Volume	24
Issue number	3
DOIs	https://doi.org/10.1145/1073204.1073283
Publication status	Published - 2005 Jul
Event	ACM SIGGRAPH 2005 - Los Angeles, CA, United States Duration: 2005 Jul 31 → 2005 Aug 4

Keywords

Bubbly water
Capillary instability
Multi-phase fluid
Natural phenomena
Surface tension
Viscosity

ASJC Scopus subject areas

Computer Graphics and Computer-Aided Design

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10.1145/1073204.1073283

Cite this

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abstract = "At interfaces between different fluids, properties such as density, viscosity, and molecular cohesion are discontinuous. To animate small-scale details of incompressible viscous multi-phase fluids realistically, we focus on the discontinuities in the state variables that express these properties. Surface tension of both free and bubble surfaces is modeled using the jump condition in the pressure field; and discontinuities in the velocity gradient field, driven by viscosity differences, are also considered. To obtain derivatives of the pressure and velocity fields with sub-grid accuracy, they are extrapolated across interfaces using continuous variables based on physical properties. The numerical methods that we present are easy to implement and do not impact the performance of existing solvers. Small-scale fluid motions, such as capillary instability, breakup of liquid sheets, and bubbly water can all be successfully animated.",

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T1 - Discontinuous fluids

AU - Hong, Jeong Mo

AU - Kim, Chang Hun

PY - 2005/7

Y1 - 2005/7

N2 - At interfaces between different fluids, properties such as density, viscosity, and molecular cohesion are discontinuous. To animate small-scale details of incompressible viscous multi-phase fluids realistically, we focus on the discontinuities in the state variables that express these properties. Surface tension of both free and bubble surfaces is modeled using the jump condition in the pressure field; and discontinuities in the velocity gradient field, driven by viscosity differences, are also considered. To obtain derivatives of the pressure and velocity fields with sub-grid accuracy, they are extrapolated across interfaces using continuous variables based on physical properties. The numerical methods that we present are easy to implement and do not impact the performance of existing solvers. Small-scale fluid motions, such as capillary instability, breakup of liquid sheets, and bubbly water can all be successfully animated.

AB - At interfaces between different fluids, properties such as density, viscosity, and molecular cohesion are discontinuous. To animate small-scale details of incompressible viscous multi-phase fluids realistically, we focus on the discontinuities in the state variables that express these properties. Surface tension of both free and bubble surfaces is modeled using the jump condition in the pressure field; and discontinuities in the velocity gradient field, driven by viscosity differences, are also considered. To obtain derivatives of the pressure and velocity fields with sub-grid accuracy, they are extrapolated across interfaces using continuous variables based on physical properties. The numerical methods that we present are easy to implement and do not impact the performance of existing solvers. Small-scale fluid motions, such as capillary instability, breakup of liquid sheets, and bubbly water can all be successfully animated.

KW - Bubbly water

KW - Capillary instability

KW - Multi-phase fluid

KW - Natural phenomena

KW - Surface tension

KW - Viscosity

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Discontinuous fluids

Abstract

Keywords

ASJC Scopus subject areas

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