Predicting the effect of droplet geometry and size distribution on atmospheric corrosion

Nils Van Den Steen; Yaiza Gonzalez-Garcia; J.M.C. Mol; Herman Terryn; Yves Van Ingelgem

Predicting the effect of droplet geometry and size distribution on atmospheric corrosion

Nils Van Den Steen, Yaiza Gonzalez-Garcia, J.M.C. Mol, Herman Terryn, Yves Van Ingelgem

Onderzoeksoutput: Article › peer review

21 Citaten (Scopus)

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A new approach is proposed to numerically predict and study atmospheric corrosion for ranging droplet size distributions and the influence of the droplet geometry. The proposed methodology allows for a corrosion prediction based on observed droplet size distributions and droplet contact angles. A mechanistic finite element model, including oxygen transport and Butler-Volmer kinetics, is solved in order to obtain the current density as a function of the droplet geometry. This is done for a range of both droplet radii and contact angles. The computed corrosion current densities are then used as input for imposed droplet size distributions. This allows for a calculated material loss estimation for different distributions and electrolyte configurations and shows the extent of the impact of the droplet size distribution on atmospheric corrosion.

Originele taal-2	English
Artikelnummer	110308
Tijdschrift	Corrosion Science
Volume	202
Status	Published - 1 jul 2022

Bibliografische nota

Funding Information:
This research was carried out under Project no. T18016 in the framework of the Research Program of the Materials innovation institute ( M2i ) ( www.m2i.nl ) supported by the Dutch government.

Publisher Copyright:
© 2022 Elsevier Ltd

Copyright:
Copyright 2022 Elsevier B.V., All rights reserved.

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title = "Predicting the effect of droplet geometry and size distribution on atmospheric corrosion",

abstract = "A new approach is proposed to numerically predict and study atmospheric corrosion for ranging droplet size distributions and the influence of the droplet geometry. The proposed methodology allows for a corrosion prediction based on observed droplet size distributions and droplet contact angles. A mechanistic finite element model, including oxygen transport and Butler-Volmer kinetics, is solved in order to obtain the current density as a function of the droplet geometry. This is done for a range of both droplet radii and contact angles. The computed corrosion current densities are then used as input for imposed droplet size distributions. This allows for a calculated material loss estimation for different distributions and electrolyte configurations and shows the extent of the impact of the droplet size distribution on atmospheric corrosion.",

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note = "Funding Information: This research was carried out under Project no. T18016 in the framework of the Research Program of the Materials innovation institute ( M2i ) ( www.m2i.nl ) supported by the Dutch government. Publisher Copyright: {\textcopyright} 2022 Elsevier Ltd Copyright: Copyright 2022 Elsevier B.V., All rights reserved.",

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AU - Van Den Steen, Nils

AU - Gonzalez-Garcia, Yaiza

AU - Mol, J.M.C.

AU - Terryn, Herman

AU - Van Ingelgem, Yves

N1 - Funding Information: This research was carried out under Project no. T18016 in the framework of the Research Program of the Materials innovation institute ( M2i ) ( www.m2i.nl ) supported by the Dutch government. Publisher Copyright: © 2022 Elsevier Ltd Copyright: Copyright 2022 Elsevier B.V., All rights reserved.

PY - 2022/7/1

Y1 - 2022/7/1

N2 - A new approach is proposed to numerically predict and study atmospheric corrosion for ranging droplet size distributions and the influence of the droplet geometry. The proposed methodology allows for a corrosion prediction based on observed droplet size distributions and droplet contact angles. A mechanistic finite element model, including oxygen transport and Butler-Volmer kinetics, is solved in order to obtain the current density as a function of the droplet geometry. This is done for a range of both droplet radii and contact angles. The computed corrosion current densities are then used as input for imposed droplet size distributions. This allows for a calculated material loss estimation for different distributions and electrolyte configurations and shows the extent of the impact of the droplet size distribution on atmospheric corrosion.

AB - A new approach is proposed to numerically predict and study atmospheric corrosion for ranging droplet size distributions and the influence of the droplet geometry. The proposed methodology allows for a corrosion prediction based on observed droplet size distributions and droplet contact angles. A mechanistic finite element model, including oxygen transport and Butler-Volmer kinetics, is solved in order to obtain the current density as a function of the droplet geometry. This is done for a range of both droplet radii and contact angles. The computed corrosion current densities are then used as input for imposed droplet size distributions. This allows for a calculated material loss estimation for different distributions and electrolyte configurations and shows the extent of the impact of the droplet size distribution on atmospheric corrosion.

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M3 - Article

VL - 202

JO - Corrosion Science

JF - Corrosion Science

SN - 0010-938X

M1 - 110308

ER -

Predicting the effect of droplet geometry and size distribution on atmospheric corrosion

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