What are the factors that contribute to corrosion in lead-cooled reactors, specifically in relation to 316L stainless steel?
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Corrosion in lead-cooled reactors, specifically in relation to 316L stainless steel, is influenced by several factors. The presence of oxygen in the coolant significantly affects the corrosion behavior of 316L stainless steel, with higher oxygen levels leading to the formation of multi-oxide layers on the alloy surface . The corrosion depth and the type of oxide product formed also depend on the oxygen content, with higher oxygen levels resulting in dissolution corrosion and the formation of a dense Fe-Cr oxide layer . Additionally, the flow velocity of the lead coolant plays a role in the corrosion process, with higher velocities leading to erosion-corrosion and affecting the thickness of the affected zone . The dissolution and mass transfer of alloying elements, such as nickel, from the structural materials to the coolant also contribute to corrosion in lead-cooled reactors .
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1 Citations | The provided paper does not specifically discuss the factors that contribute to corrosion in lead-cooled reactors. The paper focuses on the flow accelerated corrosion of stainless steel 316L by a rotating disk in a lead-bismuth eutectic melt. |
| The provided paper is about the corrosion behavior of 316Ti stainless steel in lead-bismuth eutectic (LBE), not specifically about 316L stainless steel. Therefore, the paper does not provide information on the factors contributing to corrosion in lead-cooled reactors for 316L stainless steel. | |
| The factors that contribute to corrosion in lead-cooled reactors, specifically in relation to 316L stainless steel, are not mentioned in the provided paper. | |
| The paper does not specifically mention the factors that contribute to corrosion in lead-cooled reactors, particularly in relation to 316L stainless steel. |
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