Electrochemical impedance modeling of the passivity of carbon steel in simulated concrete pore water

Digby D. Macdonald; Samin Sharifi Asl; Ahmed Almarzooqi; George R. Engelhardt; Bruno Kursten

doi:10.1149/05030.0041ecst

Electrochemical impedance modeling of the passivity of carbon steel in simulated concrete pore water

Digby D. Macdonald, Samin Sharifi Asl, Ahmed Almarzooqi, George R. Engelhardt, Bruno Kursten

King Fahd University of Petroleum & Minerals

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

3 Scopus citations

Abstract

The prediction of corrosion damage to times that are experimentally inaccessible by a large factor (e.g., to over 1000 years) is vitally important in assessing various concepts for the disposal of High Level Nuclear Waste. Such prediction can only be made using deterministic models, whose predictions are constrained to being physically real by the natural laws [conservation of mass, energy, charge and mass-charge equivalence (Faraday's Law)]. In this paper, we describe the measurement of experimental data that will allow the deterministic prediction of damage to the carbon steel overpack of the super container in Belgium's proposed Boom Clay repository by using the Point Defect Model to extrapolate damage to future times. We also describe an experimental program that is designed to generate values for various PDM parameters for the corrosion of carbon steel and stainless steel that will be required in making the damage predictions.

Original language	English
Title of host publication	Materials Degradation in Energy Systems
Subtitle of host publication	Corrosion and Hydrogen-Material Interactions
Publisher	Electrochemical Society Inc.
Pages	41-56
Number of pages	16
Edition	30
ISBN (Print)	9781607684183
DOIs	https://doi.org/10.1149/05030.0041ecst
State	Published - 2013

Publication series

Name	ECS Transactions
Number	30
Volume	50
ISSN (Print)	1938-5862
ISSN (Electronic)	1938-6737

ASJC Scopus subject areas

General Engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1149/05030.0041ecst

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Macdonald, D. D., Asl, S. S., Almarzooqi, A., Engelhardt, G. R., & Kursten, B. (2013). Electrochemical impedance modeling of the passivity of carbon steel in simulated concrete pore water. In Materials Degradation in Energy Systems: Corrosion and Hydrogen-Material Interactions (30 ed., pp. 41-56). (ECS Transactions; Vol. 50, No. 30). Electrochemical Society Inc.. https://doi.org/10.1149/05030.0041ecst

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title = "Electrochemical impedance modeling of the passivity of carbon steel in simulated concrete pore water",

abstract = "The prediction of corrosion damage to times that are experimentally inaccessible by a large factor (e.g., to over 1000 years) is vitally important in assessing various concepts for the disposal of High Level Nuclear Waste. Such prediction can only be made using deterministic models, whose predictions are constrained to being physically real by the natural laws [conservation of mass, energy, charge and mass-charge equivalence (Faraday's Law)]. In this paper, we describe the measurement of experimental data that will allow the deterministic prediction of damage to the carbon steel overpack of the super container in Belgium's proposed Boom Clay repository by using the Point Defect Model to extrapolate damage to future times. We also describe an experimental program that is designed to generate values for various PDM parameters for the corrosion of carbon steel and stainless steel that will be required in making the damage predictions.",

author = "Macdonald, \{Digby D.\} and Asl, \{Samin Sharifi\} and Ahmed Almarzooqi and Engelhardt, \{George R.\} and Bruno Kursten",

year = "2013",

doi = "10.1149/05030.0041ecst",

language = "English",

isbn = "9781607684183",

series = "ECS Transactions",

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booktitle = "Materials Degradation in Energy Systems",

edition = "30",

}

Macdonald, DD, Asl, SS, Almarzooqi, A, Engelhardt, GR & Kursten, B 2013, Electrochemical impedance modeling of the passivity of carbon steel in simulated concrete pore water. in Materials Degradation in Energy Systems: Corrosion and Hydrogen-Material Interactions. 30 edn, ECS Transactions, no. 30, vol. 50, Electrochemical Society Inc., pp. 41-56. https://doi.org/10.1149/05030.0041ecst

Electrochemical impedance modeling of the passivity of carbon steel in simulated concrete pore water. / Macdonald, Digby D.; Asl, Samin Sharifi; Almarzooqi, Ahmed et al.
Materials Degradation in Energy Systems: Corrosion and Hydrogen-Material Interactions. 30. ed. Electrochemical Society Inc., 2013. p. 41-56 (ECS Transactions; Vol. 50, No. 30).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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T1 - Electrochemical impedance modeling of the passivity of carbon steel in simulated concrete pore water

AU - Macdonald, Digby D.

AU - Asl, Samin Sharifi

AU - Almarzooqi, Ahmed

AU - Engelhardt, George R.

AU - Kursten, Bruno

PY - 2013

Y1 - 2013

N2 - The prediction of corrosion damage to times that are experimentally inaccessible by a large factor (e.g., to over 1000 years) is vitally important in assessing various concepts for the disposal of High Level Nuclear Waste. Such prediction can only be made using deterministic models, whose predictions are constrained to being physically real by the natural laws [conservation of mass, energy, charge and mass-charge equivalence (Faraday's Law)]. In this paper, we describe the measurement of experimental data that will allow the deterministic prediction of damage to the carbon steel overpack of the super container in Belgium's proposed Boom Clay repository by using the Point Defect Model to extrapolate damage to future times. We also describe an experimental program that is designed to generate values for various PDM parameters for the corrosion of carbon steel and stainless steel that will be required in making the damage predictions.

AB - The prediction of corrosion damage to times that are experimentally inaccessible by a large factor (e.g., to over 1000 years) is vitally important in assessing various concepts for the disposal of High Level Nuclear Waste. Such prediction can only be made using deterministic models, whose predictions are constrained to being physically real by the natural laws [conservation of mass, energy, charge and mass-charge equivalence (Faraday's Law)]. In this paper, we describe the measurement of experimental data that will allow the deterministic prediction of damage to the carbon steel overpack of the super container in Belgium's proposed Boom Clay repository by using the Point Defect Model to extrapolate damage to future times. We also describe an experimental program that is designed to generate values for various PDM parameters for the corrosion of carbon steel and stainless steel that will be required in making the damage predictions.

UR - https://www.scopus.com/pages/publications/84885769999

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DO - 10.1149/05030.0041ecst

M3 - Conference contribution

AN - SCOPUS:84885769999

SN - 9781607684183

T3 - ECS Transactions

SP - 41

EP - 56

BT - Materials Degradation in Energy Systems

PB - Electrochemical Society Inc.

ER -

Electrochemical impedance modeling of the passivity of carbon steel in simulated concrete pore water

Abstract

Publication series

ASJC Scopus subject areas

UN SDGs

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