Natural and Marangoni convection in partially miscible liquid systems

R. Savino; C. Piccolo; M. Lappa; L. Carotenuto

doi:10.1016/j.actaastro.2005.03.040

Natural and Marangoni convection in partially miscible liquid systems

R. Savino, C. Piccolo, M. Lappa, L. Carotenuto

Mechanical And Aerospace Engineering

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

3 Citations (Scopus)

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Abstract

This article deals with laboratory experiments and numerical simulations of convection and dissolution phenomena in partially miscible liquids. Transparent organic liquids (cyclohexane and methanol) are considered as a model system to study problems occurring during solidification of metal alloys with a miscibility gap. Non-invasive optical techniques are used to study stable and unstable convective solutal plumes, that are produced at the tip of a liquid droplet dissolving in a non- isothermal partially miscible liquid. Numerical simulations explain the observed behaviour and capture additional insights into the physics of the phenomenon, following from a delicate balance between counteracting buoyancy and surface tension- driven flows.

Original language	English
Pages (from-to)	89-96
Number of pages	8
Journal	Acta Astronautica
Volume	57
Issue number	2-8
DOIs	https://doi.org/10.1016/j.actaastro.2005.03.040
Publication status	Published - 13 May 2005

Keywords

Marangoni convection
numerical simulations
dissolution phenomena
partially miscible liquids

Access to Document

10.1016/j.actaastro.2005.03.040

ActaAstronautica-57-p89-(2005)-AUTHOR_POST-PRINTAccepted author manuscript, 625 KB

Cite this

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title = "Natural and Marangoni convection in partially miscible liquid systems",

abstract = "This article deals with laboratory experiments and numerical simulations of convection and dissolution phenomena in partially miscible liquids. Transparent organic liquids (cyclohexane and methanol) are considered as a model system to study problems occurring during solidification of metal alloys with a miscibility gap. Non-invasive optical techniques are used to study stable and unstable convective solutal plumes, that are produced at the tip of a liquid droplet dissolving in a non- isothermal partially miscible liquid. Numerical simulations explain the observed behaviour and capture additional insights into the physics of the phenomenon, following from a delicate balance between counteracting buoyancy and surface tension- driven flows.",

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T1 - Natural and Marangoni convection in partially miscible liquid systems

AU - Savino, R.

AU - Piccolo, C.

AU - Lappa, M.

AU - Carotenuto, L.

PY - 2005/5/13

Y1 - 2005/5/13

N2 - This article deals with laboratory experiments and numerical simulations of convection and dissolution phenomena in partially miscible liquids. Transparent organic liquids (cyclohexane and methanol) are considered as a model system to study problems occurring during solidification of metal alloys with a miscibility gap. Non-invasive optical techniques are used to study stable and unstable convective solutal plumes, that are produced at the tip of a liquid droplet dissolving in a non- isothermal partially miscible liquid. Numerical simulations explain the observed behaviour and capture additional insights into the physics of the phenomenon, following from a delicate balance between counteracting buoyancy and surface tension- driven flows.

AB - This article deals with laboratory experiments and numerical simulations of convection and dissolution phenomena in partially miscible liquids. Transparent organic liquids (cyclohexane and methanol) are considered as a model system to study problems occurring during solidification of metal alloys with a miscibility gap. Non-invasive optical techniques are used to study stable and unstable convective solutal plumes, that are produced at the tip of a liquid droplet dissolving in a non- isothermal partially miscible liquid. Numerical simulations explain the observed behaviour and capture additional insights into the physics of the phenomenon, following from a delicate balance between counteracting buoyancy and surface tension- driven flows.

KW - Marangoni convection

KW - numerical simulations

KW - dissolution phenomena

KW - partially miscible liquids

U2 - 10.1016/j.actaastro.2005.03.040

DO - 10.1016/j.actaastro.2005.03.040

M3 - Article

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EP - 96

JO - Acta Astronautica

JF - Acta Astronautica

SN - 0094-5765

IS - 2-8

ER -