Synergy Effect of Simultaneous Zinc and Nickel Addition on Cobalt Deposition onto Stainless Steel in Oxygenated High Temperature Water

Inagaki, Hidetoshi; Nishikawa, Akira; Sato, Yuji; Tsuji, Takeshi

doi:10.3327/jnst.40.143

Cited by 8 publications

(8 citation statements)

References 23 publications

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“…1,2 It is hence known that the oxide films formed on stainless steels and nickel-based alloys in high-temperature water have basically the same main structure and that the important compounds ensuring the protective character of the oxide film ͑nickel ferrite and nickel and iron chromites͒ are essentially the same for all the nickel-based materials and stainless steels. [3][4][5][6][7][8][9][10][11][12][13][14][15] In addition to the increased understanding of growth and restructuring of oxide films, recent development of radiolysis codes allows the modeling of the chemistry resulting from the radiolysis in virtually any location where the coolant is in contact with any material in light water reactors. The modeling provides the concentration of all radiolysis products, including radicals, and also calculates the local electrochemical corrosion potential in each location, hence providing the basis for determining or establishing thermodynamic, kinetic, and electrokinetic phenomena.…”

mentioning

confidence: 99%

A Mixed-Conduction Model for the Oxidation of Stainless Steel in a High-Temperature Electrolyte

Bojinov

Kinnunen

Lundgren³

et al. 2005

J. Electrochem. Soc.

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The oxide films formed on AISI 316L͑NG͒ in the temperature range 150-300°C have been characterized by impedance spectroscopy and ex situ analysis using Auger electron spectroscopy. Relatively thick films containing a high concentration of mobile defects form on stainless steel in a high-temperature borate electrolyte, but their impedance response is most probably controlled by the properties of a thin barrier sublayer. The ability of the mixed conduction model for passive films to reproduce the experimental impedance data in both alloy/oxide/electrolyte and alloy/oxide/inert metal configurations has been tested. A procedure for the calculation of the kinetic constants of the interfacial reactions of point defect generation/consumption, as well as those characterizing the transport rates of ionic/electronic defects in the oxide, has been developed. The effect of temperature on the kinetic and transport parameters has been assessed, and the relevance of these parameters for the corrosion behavior of stainless steel in a high-temperature electrolyte is discussed. The results show that the nature of the barrier layer does not change drastically with temperature, although the growth mechanism of the oxide film is different at 150-300°C than at room temperature.The materials used in contact with the coolant in nuclear power plants rely almost exclusively on a passivating oxide film to ensure durability and structural integrity. A slow and well-controlled growth of the passive film is necessary in order to limit the impact of the coolant on these materials and to minimize the concentration of impurities that may reach the nuclear fuel surfaces and thus become radioactive.The development of knowledge of the oxide film composition and behavior, as well as the knowledge of the local coolant chemistries, has converged considerably during the last few years. 1,2 It is hence known that the oxide films formed on stainless steels and nickel-based alloys in high-temperature water have basically the same main structure and that the important compounds ensuring the protective character of the oxide film ͑nickel ferrite and nickel and iron chromites͒ are essentially the same for all the nickel-based materials and stainless steels. [3][4][5][6][7][8][9][10][11][12][13][14][15] In addition to the increased understanding of growth and restructuring of oxide films, recent development of radiolysis codes allows the modeling of the chemistry resulting from the radiolysis in virtually any location where the coolant is in contact with any material in light water reactors. The modeling provides the concentration of all radiolysis products, including radicals, and also calculates the local electrochemical corrosion potential in each location, hence providing the basis for determining or establishing thermodynamic, kinetic, and electrokinetic phenomena. 16 We hence have the qualitative understanding of most of the important processes during film growth and restructuring, with their background and implications. 17,18 What we still lack today i...

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mentioning

confidence: 99%

A Mixed-Conduction Model for the Oxidation of Stainless Steel in a High-Temperature Electrolyte

Bojinov

Kinnunen

Lundgren³

et al. 2005

J. Electrochem. Soc.

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“…Hydrogen is the reducing agent to dissolve the protective oxide film and that might enhance the corrosion. The results of corrosion depth measurements in pure water at 553 K under the NWC condition for 118 h (Run 2) are shown in Figure 8 along with literature data and the experimental conditions at which they were obtained [8][9][10]12,27]. Measured ECP of the NWC condition (NWC 1) was þ0.15 V vs. SHE.…”

Section: Corrosion Depthmentioning

confidence: 82%

“…The corrosion depth of 316L SS in 553 K pure water has been reported to be of the order of a micrometre or less [8][9][10][11][12]. The corrosion depths of 316L SS wire specimens (diameter 50 mm) were evaluated using electrical resistance measurements applying a constant current (I) and measuring the potential drop (V) intermittently to obtain the resistance (R) via Ohm's law (Equation (1)).…”

Section: Measurements Of Corrosion Depth and Ecpmentioning

confidence: 99%

“…Corrosion of stainless steel in pure water at 553 K is thought to be controlled by a parabolic rate law or a logarithmic rate law described as Equation (19) or Equation (20), respectively [7,9]. Consequently, the corrosion depth data were fitted with the equations:…”

Section: Corrosion Kineticsmentioning

confidence: 99%

“…Other reports have expressed total corrosion rate of 316L SS in oxygenated water at 553-563 K as depending upon time raised to the 2/3 power [8] or being controlled by a logarithmic rate law [9]. Corrosion depths at an early time of 200 h are about 50-80% of those at 1000 h [9,10]. So, corrosion rate at time less than 200 h is important for knowing the corrosion kinetics.…”

Section: Introductionmentioning

confidence: 99%

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In situmeasurement of corrosion of type 316L stainless steel in 553 K pure water via the electrical resistance of a thin wire

Ishida

Lister

2012

Journal of Nuclear Science and Technology

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A system for the in situ monitoring of corrosion depth via electrical resistance measurements was applied to study the corrosion rate of type 316L stainless steel at 553 K in pure water. Corrosion depth was measured using a 50 mm diameter wire probe mounted axially in the tube. Measurements were in good agreement with literature data for both the hydrogen water chemistry (HWC) condition and the normal water chemistry (NWC) condition. Oxide film analyses by scanning electron microscopy and laser Raman spectroscopy on the wire probe and the tube showed no effects from shape of the test specimens or the application of electric current. Corrosion kinetics was evaluated by fitting equations to the measurements. Data for the HWC condition could be fitted by a two-step logarithmic-parabolic law. A single-step logarithmic law fitted data for the NWC condition. Changes in corrosion rate by the water chemistry changes were readily detected with the technique. Corrosion depth change could be observed for the water chemistry change from the NWC condition to the HWC condition with electrochemical corrosion potential (ECP) of 70.56 V vs. standard hydrogen electrode, which is lower than the ECP that the phase of iron oxide changes from a-Fe 2 O 3 to Fe 3 O 4 .

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Effect of nickel ion from autoclave material on oxidation behaviour of 304 stainless steel in oxygenated high temperature water

Kuang

Han

et al. 2011

Corrosion Science

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Synergy Effect of Simultaneous Zinc and Nickel Addition on Cobalt Deposition onto Stainless Steel in Oxygenated High Temperature Water

Cited by 8 publications

References 23 publications

A Mixed-Conduction Model for the Oxidation of Stainless Steel in a High-Temperature Electrolyte

A Mixed-Conduction Model for the Oxidation of Stainless Steel in a High-Temperature Electrolyte

In situmeasurement of corrosion of type 316L stainless steel in 553 K pure water via the electrical resistance of a thin wire

Effect of nickel ion from autoclave material on oxidation behaviour of 304 stainless steel in oxygenated high temperature water

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