Mushy-layer dynamics in micro and hyper gravity

J. G. O'Rourke; A. J.E. Riggs; C. A. Guertler; P. W. Miller; C. M. Padhi; M. M. Popelka; A. J. Wells; A. C. West; J. Q. Zhong; J. S. Wettlaufer

doi:10.1063/1.4760256

Mushy-layer dynamics in micro and hyper gravity

J. G. O'Rourke, A. J.E. Riggs, C. A. Guertler, P. W. Miller, C. M. Padhi, M. M. Popelka, A. J. Wells, A. C. West, J. Q. Zhong, J. S. Wettlaufer

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

We describe the results of experiments on mushy layers grown from aqueous ammonium chloride solution in normal, micro, and hyper gravity environments. In the fully developed chimney state, the chimney plume dynamics differ strikingly when conditions change from micro to hyper gravity. In microgravity, we find fully arrested plume motion and suppressed convection. As gravity exceeds Earth conditions, we observe a host of phenomena, ranging from arched plumes that undergo forced Rayleigh-Taylor instabilities to in-phase multiple plume oscillatory behavior. For the same initial solute concentrations and fixed boundary cooling temperatures, we find that, in runs of over two hours, the averaged effects of microgravity and hypergravity result in suppressed growth of the mushy layers, a phenomenon caused by a net enhancement of convective heat and solute transport from the liquid to the mushy layers. These behaviors are placed in the context of the theory of convecting mushy layers as studied under normal laboratory conditions.

Original language	English (US)
Article number	103305
Journal	Physics of Fluids
Volume	24
Issue number	10
DOIs	https://doi.org/10.1063/1.4760256
State	Published - Oct 3 2012
Externally published	Yes

ASJC Scopus subject areas

Computational Mechanics
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering
Fluid Flow and Transfer Processes

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10.1063/1.4760256

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title = "Mushy-layer dynamics in micro and hyper gravity",

abstract = "We describe the results of experiments on mushy layers grown from aqueous ammonium chloride solution in normal, micro, and hyper gravity environments. In the fully developed chimney state, the chimney plume dynamics differ strikingly when conditions change from micro to hyper gravity. In microgravity, we find fully arrested plume motion and suppressed convection. As gravity exceeds Earth conditions, we observe a host of phenomena, ranging from arched plumes that undergo forced Rayleigh-Taylor instabilities to in-phase multiple plume oscillatory behavior. For the same initial solute concentrations and fixed boundary cooling temperatures, we find that, in runs of over two hours, the averaged effects of microgravity and hypergravity result in suppressed growth of the mushy layers, a phenomenon caused by a net enhancement of convective heat and solute transport from the liquid to the mushy layers. These behaviors are placed in the context of the theory of convecting mushy layers as studied under normal laboratory conditions.",

author = "O'Rourke, {J. G.} and Riggs, {A. J.E.} and Guertler, {C. A.} and Miller, {P. W.} and Padhi, {C. M.} and Popelka, {M. M.} and Wells, {A. J.} and West, {A. C.} and Zhong, {J. Q.} and Wettlaufer, {J. S.}",

note = "Funding Information: We thank CT Space Grant, the Yale College Dean's Office, and Yale University's Departments of Geology and Geophysics and Physics for financial support. Sara Malloy and the rest of the NASA Johnson Space Center Reduced Gravity Office and the Zero G Corporation staff provided considerable technical assistance. Jake Forsberg and Boise State University's 2011 Microgravity University team generously shared their accelerometer data. Comments from two anonymous reviewers greatly improved the clarity and content of this manuscript. J.S.W. thanks the Swedish Research Council for support of his research.",

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doi = "10.1063/1.4760256",

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T1 - Mushy-layer dynamics in micro and hyper gravity

AU - O'Rourke, J. G.

AU - Riggs, A. J.E.

AU - Guertler, C. A.

AU - Miller, P. W.

AU - Padhi, C. M.

AU - Popelka, M. M.

AU - Wells, A. J.

AU - West, A. C.

AU - Zhong, J. Q.

AU - Wettlaufer, J. S.

N1 - Funding Information: We thank CT Space Grant, the Yale College Dean's Office, and Yale University's Departments of Geology and Geophysics and Physics for financial support. Sara Malloy and the rest of the NASA Johnson Space Center Reduced Gravity Office and the Zero G Corporation staff provided considerable technical assistance. Jake Forsberg and Boise State University's 2011 Microgravity University team generously shared their accelerometer data. Comments from two anonymous reviewers greatly improved the clarity and content of this manuscript. J.S.W. thanks the Swedish Research Council for support of his research.

PY - 2012/10/3

Y1 - 2012/10/3

N2 - We describe the results of experiments on mushy layers grown from aqueous ammonium chloride solution in normal, micro, and hyper gravity environments. In the fully developed chimney state, the chimney plume dynamics differ strikingly when conditions change from micro to hyper gravity. In microgravity, we find fully arrested plume motion and suppressed convection. As gravity exceeds Earth conditions, we observe a host of phenomena, ranging from arched plumes that undergo forced Rayleigh-Taylor instabilities to in-phase multiple plume oscillatory behavior. For the same initial solute concentrations and fixed boundary cooling temperatures, we find that, in runs of over two hours, the averaged effects of microgravity and hypergravity result in suppressed growth of the mushy layers, a phenomenon caused by a net enhancement of convective heat and solute transport from the liquid to the mushy layers. These behaviors are placed in the context of the theory of convecting mushy layers as studied under normal laboratory conditions.

AB - We describe the results of experiments on mushy layers grown from aqueous ammonium chloride solution in normal, micro, and hyper gravity environments. In the fully developed chimney state, the chimney plume dynamics differ strikingly when conditions change from micro to hyper gravity. In microgravity, we find fully arrested plume motion and suppressed convection. As gravity exceeds Earth conditions, we observe a host of phenomena, ranging from arched plumes that undergo forced Rayleigh-Taylor instabilities to in-phase multiple plume oscillatory behavior. For the same initial solute concentrations and fixed boundary cooling temperatures, we find that, in runs of over two hours, the averaged effects of microgravity and hypergravity result in suppressed growth of the mushy layers, a phenomenon caused by a net enhancement of convective heat and solute transport from the liquid to the mushy layers. These behaviors are placed in the context of the theory of convecting mushy layers as studied under normal laboratory conditions.

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Mushy-layer dynamics in micro and hyper gravity

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