Kinetic Properties of the Passive Film on Copper in the Presence of Sulfate-Reducing Bacteria

Huttunen-Saarivirta, Elina; Ghanbari, Elmira; Mao, Feixiong; Rajala, Pauliina; Carpén, Leena; Macdonald, Digby D.

doi:10.1149/2.007189jes

Cited by 21 publications

(41 citation statements)

References 41 publications

(69 reference statements)

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“…Rather, the corrosion product will remain porous, such that incoming sulfide will be able to continuously react at the copper surface. Some counterarguments have been raised about this description, suggesting the films may be passive, [ 33 ] and these questions have been clarified, [ 34 ] rebutted, [ 35 ] and further debated. [ 36 ] The most recent experimental and mechanistic analyses do not support the existence of a barrier film [ 37 ] ; thus, the description of a passive sulfide film does not enter safety arguments for SKB [ 38 ] or the NWMO.…”

Section: Program Context: the Evolution Of The Nwmo Proof Test Plan (mentioning

confidence: 99%

An update on the copper corrosion program for the long‐term management of used nuclear fuel in Canada

Keech

Behazin

Binns

et al. 2020

Materials & Corrosion

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In 2012, the Nuclear Waste Management Organization developed a comprehensive proof test plan (PTP) to evaluate the feasibility and safety of their copper‐coated used fuel container and their novel bentonite buffer box emplacement concept to be employed in its proposed deep geological repository for the long‐term management of used nuclear fuel. Research within the PTP includes several programs to evaluate the possible extent of damage that may be caused by various copper corrosion mechanisms: oxic‐, radiolytic‐, anoxic‐, and sulfide‐induced, with particular attention being paid to the possibility of localization of any of these processes. Programs remain on track to support and refine a maximum copper corrosion allowance of <1.27 mm over a one million year emplacement in a deep geological repository.

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Section: Program Context: the Evolution Of The Nwmo Proof Test Plan (mentioning

confidence: 99%

An update on the copper corrosion program for the long‐term management of used nuclear fuel in Canada

Keech

Behazin

Binns

et al. 2020

Materials & Corrosion

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“…Passive film properties are described in terms of the point defect model and evidence for film breakdown and pitting have been presented. [ 34–39 ] The observation of a levelling off of the anodic current with increasing potential during cyclic voltammetry is consistent with passive behaviour, [ 37 ] although the observed current is the same on the forward and reverse potential scans, which would not be expected if a passive film had been formed on the forward scan. [ 41 ] Martino et al [ 41 ] also suggested that the reported film breakdown events [ 34,36 ] were instead the onset of rapid anodic dissolution of copper as CuCl 2 − species through a porous Cu 2 S film.…”

Section: Canister Evolutionmentioning

confidence: 63%

“…One example of this difference between laboratory and repository conditions relates to the properties of the Cu 2 S formed on copper in sulphide‐containing environments. There has been a recent debate in the literature about whether these films should be classified as passive [ 34–39 ] or porous. [ 1–4, 40,41 ] Although there is no strict definition of a passive versus a porous film, the important distinction here is that passive films could be subject to localised breakdown and pitting, [ 34–37 ] whereas a copper surface covered by a porous film would tend to corrode relatively uniformly.…”

Section: Canister Evolutionmentioning

confidence: 99%

Status report of the Finnish spent fuel geologic repository programme and ongoing corrosion studies

Salonen

Lamminmäki

King³

et al. 2020

Materials & Corrosion

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Posiva Oy is preparing to submit an operating licence application for a spent nuclear fuel geologic repository located at Olkiluoto, Finland. The construction licence for the underground disposal facility and encapsulation plant was granted in 2015 and construction of the disposal facility began in December 2016. Safe disposal is achieved by the KBS‐3 concept, developed in collaboration with Posiva's Swedish counterpart, the Swedish Nuclear Fuel and Waste Management Co, (SKB). The KBS‐3 concept consists of disposal canisters (a cast iron insert and a copper overpack), surrounded by swelling bentonite and disposed in crystalline bedrock. The copper overpack ensures containment of radioactive materials and its performance against corrosion is a key driver for the design of the engineered barrier system and the repository overall. This paper describes the current status of the Posiva programme, recent learnings from the construction of the repository, and the implications for the long‐term performance of the canister.

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“…The general solution of the ODE was obtained by introducing expressions (25) and (26) in (24). Then, using the initial condition, the value of was determined; obtaining in this way the unique solution of the Cauchy problem.…”

Section: Solution Of the Cauchy Problemmentioning

confidence: 99%

“…Electrochemical impedance spectroscopy (EIS) is a non-destructive electrochemical method, with a broad range of applications in different fields of electrochemical science and engineering, among which are, for example, energy storage [1][2], batteries [3][4][5][6][7][8], electrochemical sensors [9][10][11][12], fuel cells [13][14][15][16][17][18], electrolysers [19][20][21], corrosion and coatings [22][23][24][25], and bioelectrochemistry [26,27]. The power of this electrochemical technique arises from its ability to distinguish the different physicchemical processes undergoing at different timescales in the system [28].…”

Section: Introductionmentioning

confidence: 99%

Theoretical Determination of the Stabilization Time in Galvanostatic EIS Measurements: The Simplified Randles Cell

Giner-Sanz¹,

Ortega²,

García-Gabaldón³

et al. 2018

J. Electrochem. Soc.

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Usually, EIS measurements are performed in 2 steps: a stabilization step followed by an acquisition step. The first is necessary in order to ensure that the impedance is determined when the system has reached its stationary state. In this work, a theoretical framework is proposed for estimating the required stabilization time for EIS measurements. Here, it was applied to the simplest case: the simplified Randles cell. In order to calculate the required stabilization time for performing EIS measurements, a theoretical dynamic model of a Randles cell under galvanostatic sinusoidal perturbation was developed. The proposed model can be used to estimate, from a theoretical point of view, the required stabilization time for performing EIS measurements in a Randles-like system. Even though, this work focuses on the simplest case, the developed theoretical framework can be applied to any system, however complex it may be.

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Kinetic Properties of the Passive Film on Copper in the Presence of Sulfate-Reducing Bacteria

Cited by 21 publications

References 41 publications

An update on the copper corrosion program for the long‐term management of used nuclear fuel in Canada

An update on the copper corrosion program for the long‐term management of used nuclear fuel in Canada

Status report of the Finnish spent fuel geologic repository programme and ongoing corrosion studies

Theoretical Determination of the Stabilization Time in Galvanostatic EIS Measurements: The Simplified Randles Cell

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