Dissolution and Passivation of a Silicon-Rich Austenitic Stainless Steel during Active-Passive Cycles in Sulfuric and Nitric Acid

Laurent, B.; Gruet, N.; Gwinner, B.; Miserque, F.; Rousseau, K.; Ogle, K.

doi:10.1149/2.1531713jes

Cited by 21 publications

(14 citation statements)

References 49 publications

(89 reference statements)

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“…This is in accordance with the results of Tcharkhtchi et al who showed an increase of the oxide thickness of a 304L SS in nitric acid with the increase of the corrosion potential Ecorr [26]. for these SSs corroded in nitric acid media [26,43,61], the oxide is mainly composed of chromium with a small proportion of iron. Nickel oxide is not observed.…”

Section: Potential Vs She [V]supporting

confidence: 92%

Intergranular corrosion in evolving media: Experiment and modeling by cellular automata

et al. 2022

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Section: Potential Vs She [V]supporting

confidence: 92%

Intergranular corrosion in evolving media: Experiment and modeling by cellular automata

et al. 2022

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“…Nitric acid is a strong oxidant, and stainless steels spontaneously passivate in concentrated nitric acid solutions and remain passive at open-circuit potential (OCP) conditions. 24 Laurent et al investigated two stainless steels with low and high Si content in nitric acid and concluded that their passive layer was similar at the end of passivation. The naturally formed passive film over the ferrite is different than that of the austenite, giving rise to a typical Volta potential difference of 40-70 mV of numerous DSS's.…”

Section: Effect Of Nitric Acid Oxidation On the Passive Filmmentioning

confidence: 99%

“…The naturally formed passive film over the ferrite is different than that of the austenite, giving rise to a typical Volta potential difference of 40-70 mV of numerous DSS's. 12,13,19,25 Laurent et al 24 reported a chromium-rich oxide, in the form of chromia, that became further enriched in the passive film upon passivation in nitric acid, with the thickness, however, not been majorly altered. This may explain the reason why the Volta potential of ferrite and austenite of the DSS were similar after immersion in nitric acid.…”

Section: Effect Of Nitric Acid Oxidation On the Passive Filmmentioning

confidence: 99%

“…26 The passive film of stainless steels is known to be composed of an outer iron-rich oxide, mainly Fe 2 O 3 and Fe(OH) 2 /Fe(OH) 3 , and an inner chromiumrich oxide, often stated as Cr 2 O 3 and Cr(OH) 3 , with also some molybdenum as well as silicon species. [22][23][24]27 The composition and morphology as well as defect contents and semiconductor properties of passive films of stainless steel can largely differ depending on the environment in which they form. In earlier work, it was shown that the native passive film on the studied alloy gets more defective upon anodic polarisation from its passive to transpassive potential regime in 1 M NaCl solution, and becomes thicker and changes its composition and structure.…”

Section: Effect Of Nitric Acid Oxidation On the Passive Filmmentioning

confidence: 99%

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Passive film characterisation of duplex stainless steel using scanning Kelvin probe force microscopy in combination with electrochemical measurements

2019

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The characterisation of passive oxide films on heterogeneous microstructures is needed to assess local degradation (corrosion, cracking) in aggressive environments. The Volta potential is a surface-sensitive parameter which can be used to assess the surface nobility and hence passive films. In this work, it is shown that the Volta potential, measured on super duplex stainless steel by scanning Kelvin probe force microscopy, correlates with the electrochemical properties of the passive film, measured by electrochemical impedance spectroscopy and potentiodynamic polarisation. Natural oxidation by ageing in ambient air as well as artificial oxidation by immersion in concentrated nitric acid improved the nobility, both reflected by increased Volta potentials and electrochemical parameters. Passivation was associated with vanishing of the inherent Volta potential difference between the ferrite and austenite, thereby reducing the galvanic coupling and hence improving the corrosion resistance of the material. Hydrogen-passive film interactions, triggered by cathodic polarisation, however, largely increased the Volta potential difference between the phases, resulting in loss of electrochemical nobility, with the ferrite being more affected than the austenite. A correlative approach of using the Volta potential in conjunction with electrochemical data has been introduced to characterise the nobility of passive films in global and local scale.

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“…[ 32 ] The role of Si alloying on the evolution of the passive film was investigated using a similar activation‐passivation cycle, whereby a noticeable release of Si during activation confirmed the contribution of Si to the passive film of austenitic stainless steel. [ 33 ] However, the decay in the dissolution rate during passivation was found to predominantly follow the enrichment of Cr(III) oxides in the film. It indicates that in spite of enrichment in the passive film, the Si(IV) oxide did not contribute much to the passivity of stainless steel.…”

Section: Corrosion Case Studiesmentioning

confidence: 99%

Recent insights in corrosion science from atomic spectroelectrochemistry

Choudhary

Ogle

Gharbi

et al. 2021

Electrochemical Science Adv

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A fundamental understanding of corrosion mechanisms is the key to developing suitable corrosion protection approaches, and for the prediction of service life of metallic structures. However, conventional corrosion testing methods such as mass loss and electrochemical testing do not guarantee estimation of "true" corrosion rate and often mask the underlying mechanisms, due to either low sensitivity or a lack of element-resolved information. Relatively recent work in corrosion science has led to the development of a new class of corrosion testing approaches, namely atomic spectroelectrochemistry; whereby direct insight of dissolution and corrosion mechanisms can be obtained during electrochemical testing. Atomic spectroelectrochemistry provides real-time and element resolved dissolution rate of material via coupling electrochemical flow cell with inductively coupled plasma -atomic spectroscopy. This concise review discusses the basic working principle of atomic spectroelectrochemistry and its recent applications in corrosion science to understand the true underlying corrosion mechanisms of a range of metallic materials.

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Dissolution and Passivation of a Silicon-Rich Austenitic Stainless Steel during Active-Passive Cycles in Sulfuric and Nitric Acid

Cited by 21 publications

References 49 publications

Intergranular corrosion in evolving media: Experiment and modeling by cellular automata

Intergranular corrosion in evolving media: Experiment and modeling by cellular automata

Passive film characterisation of duplex stainless steel using scanning Kelvin probe force microscopy in combination with electrochemical measurements

Recent insights in corrosion science from atomic spectroelectrochemistry

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