<p>In pressurized water reactors (PWR), intergranular oxidation of structural materials in the primary‑coolant circuit is accelerated by plastic deformation concentrating along random high‑angle grain boundaries (RHAGBs), providing a precursor state for intergranular stress corrosion cracking (IGSCC). However, because IGSCC initiation is inherently stochastic, conventional macroscopic strain descriptors are ineffective at identifying which oxidized RHAGBs will eventually crack. This limitation motivates a focused search for mechanistic signatures that distinguish vulnerable boundaries from benign ones. Here, we evaluate RHAGB oxidation morphology as a potential mechanistic signature by comparing solution‑annealed (SA) and cold‑tensile‑strained (CTS) Fe–18Cr–14Ni exposed to simulated PWR primary‑water environments. Electron microscopy reveals a deformation-driven transition in RHAGB oxidation morphology, from continuous oxides in SA to complex non-planar morphologies in CTS comprising Cr-enriched filaments advancing ahead of the oxidation front. We propose a “Leading Filament” mechanism to explain this transition, where short-circuit transport enables high-aspect-ratio, stress-concentrating filaments. While macroscopic strain controls oxidation depth, boundary-specific strain heterogeneity likely governs filament morphology, offering a mechanistic descriptor relevant to the boundary-to-boundary variability in IGSCC initiation.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Strain-induced topological transition from planar to filamentous grain boundary oxidation in austenitic stainless steel

  • Semanti Mukhopadhyay,
  • Tingkun Liu,
  • Matthew Olszta,
  • Hyoju Park,
  • Ziqing Zhai,
  • Mychailo Toloczko,
  • Arun Devaraj

摘要

In pressurized water reactors (PWR), intergranular oxidation of structural materials in the primary‑coolant circuit is accelerated by plastic deformation concentrating along random high‑angle grain boundaries (RHAGBs), providing a precursor state for intergranular stress corrosion cracking (IGSCC). However, because IGSCC initiation is inherently stochastic, conventional macroscopic strain descriptors are ineffective at identifying which oxidized RHAGBs will eventually crack. This limitation motivates a focused search for mechanistic signatures that distinguish vulnerable boundaries from benign ones. Here, we evaluate RHAGB oxidation morphology as a potential mechanistic signature by comparing solution‑annealed (SA) and cold‑tensile‑strained (CTS) Fe–18Cr–14Ni exposed to simulated PWR primary‑water environments. Electron microscopy reveals a deformation-driven transition in RHAGB oxidation morphology, from continuous oxides in SA to complex non-planar morphologies in CTS comprising Cr-enriched filaments advancing ahead of the oxidation front. We propose a “Leading Filament” mechanism to explain this transition, where short-circuit transport enables high-aspect-ratio, stress-concentrating filaments. While macroscopic strain controls oxidation depth, boundary-specific strain heterogeneity likely governs filament morphology, offering a mechanistic descriptor relevant to the boundary-to-boundary variability in IGSCC initiation.