Analogy between Creeping Flows in Cavities and Thermodynamic Phase Transitions

Petru S Fodor; Miron Kaufman

Analogy between Creeping Flows in Cavities and Thermodynamic Phase Transitions

Petru S Fodor
, Miron Kaufman

Physics

Research output: Contribution to conference › Paper

Abstract

We discuss the analogy between the stream line function of creeping flows in rectangular cavities and the thermodynamic potential at critical points and at phase transitions. Assuming no-slip boundary conditions, the corners of the rectangular cavity are fixed points. We analyze two such points: 1. Corner where one wall is moving and the other is stationary; 2. Corner where both walls are stationary. The first one is analogous to a to a thermodynamic first-order transition point while the second one is analogous to a thermodynamic critical point. Moffatt eddies, which impede mixing [P. S. Fodor, M. Kaufman, Proceedings of PPS-30, AIP Conf. Proc. 1664 (2015)], are present in the neighborhood of the second stationary point. The results discussed here are based on numerical solutions of the Navier- Stokes equations combined with analytical work valid in the vicinity of the fixed points

Original language	English
State	Published - 2019
Event	8th International Symposium on Bifurcations and Instabilities in Fluid Dynamics - Limerick, Ireland Duration: Jan 1 2019 → …

Conference

Conference	8th International Symposium on Bifurcations and Instabilities in Fluid Dynamics
Period	01/1/19 → …

Cite this

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title = "Analogy between Creeping Flows in Cavities and Thermodynamic Phase Transitions",

abstract = "We discuss the analogy between the stream line function of creeping flows in rectangular cavities and the thermodynamic potential at critical points and at phase transitions. Assuming no-slip boundary conditions, the corners of the rectangular cavity are fixed points. We analyze two such points: 1. Corner where one wall is moving and the other is stationary; 2. Corner where both walls are stationary. The first one is analogous to a to a thermodynamic first-order transition point while the second one is analogous to a thermodynamic critical point. Moffatt eddies, which impede mixing [P. S. Fodor, M. Kaufman, Proceedings of PPS-30, AIP Conf. Proc. 1664 (2015)], are present in the neighborhood of the second stationary point. The results discussed here are based on numerical solutions of the Navier- Stokes equations combined with analytical work valid in the vicinity of the fixed points",

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year = "2019",

language = "English",

note = "8th International Symposium on Bifurcations and Instabilities in Fluid Dynamics ; Conference date: 01-01-2019",

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T1 - Analogy between Creeping Flows in Cavities and Thermodynamic Phase Transitions

AU - Fodor, Petru S

AU - Kaufman, Miron

PY - 2019

Y1 - 2019

N2 - We discuss the analogy between the stream line function of creeping flows in rectangular cavities and the thermodynamic potential at critical points and at phase transitions. Assuming no-slip boundary conditions, the corners of the rectangular cavity are fixed points. We analyze two such points: 1. Corner where one wall is moving and the other is stationary; 2. Corner where both walls are stationary. The first one is analogous to a to a thermodynamic first-order transition point while the second one is analogous to a thermodynamic critical point. Moffatt eddies, which impede mixing [P. S. Fodor, M. Kaufman, Proceedings of PPS-30, AIP Conf. Proc. 1664 (2015)], are present in the neighborhood of the second stationary point. The results discussed here are based on numerical solutions of the Navier- Stokes equations combined with analytical work valid in the vicinity of the fixed points

AB - We discuss the analogy between the stream line function of creeping flows in rectangular cavities and the thermodynamic potential at critical points and at phase transitions. Assuming no-slip boundary conditions, the corners of the rectangular cavity are fixed points. We analyze two such points: 1. Corner where one wall is moving and the other is stationary; 2. Corner where both walls are stationary. The first one is analogous to a to a thermodynamic first-order transition point while the second one is analogous to a thermodynamic critical point. Moffatt eddies, which impede mixing [P. S. Fodor, M. Kaufman, Proceedings of PPS-30, AIP Conf. Proc. 1664 (2015)], are present in the neighborhood of the second stationary point. The results discussed here are based on numerical solutions of the Navier- Stokes equations combined with analytical work valid in the vicinity of the fixed points

M3 - Paper

T2 - 8th International Symposium on Bifurcations and Instabilities in Fluid Dynamics

Y2 - 1 January 2019

ER -