Python/耐烧蚀合金智能体/wiki/.llm-wiki/review.json

[
  {
    "type": "missing-page",
    "title": "固溶强化机制详解",
    "description": "分析中提到\"固溶强化\"是高熵合金高强度的主要机制之一，但当前 Wiki 中仅有概念提及，缺乏 dedicated 页面详细解释其物理机制、数学模型及与其他强化机制的对比。",
    "sourcePath": "C:/Python/产品需求文档AI生成/耐烧蚀高分子/耐烧蚀高分子/raw/sources/高熵合金制备及应用研究进展_宫书林.pdf",
    "affectedPages": [
      "wiki/concepts/高熵合金四大效应.md",
      "wiki/concepts/高熵合金制备工艺.md"
    ],
    "searchQueries": [
      "solid solution strengthening mechanism high entropy alloys",
      "lattice distortion dislocation motion HEA",
      "strengthening mechanisms comparison precipitation solid solution"
    ],
    "options": [
      {
        "label": "Create Page",
        "action": "Create Page"
      },
      {
        "label": "Skip",
        "action": "Skip"
      }
    ],
    "id": "review-1",
    "resolved": true,
    "createdAt": 1779605204057,
    "resolvedAction": "Created: wiki/concepts/-2026-05-24.md"
  },
  {
    "type": "missing-page",
    "title": "钝化膜形成机理",
    "description": "耐蚀性是高熵合金的重要性能，钝化膜的形成机理、成分（Cr、Ni、Co 富集）及稳定性影响耐蚀性能，当前 Wiki 中仅在选区激光熔化页面提及，建议创建专门页面。",
    "sourcePath": "C:/Python/产品需求文档AI生成/耐烧蚀高分子/耐烧蚀高分子/raw/sources/高熵合金制备及应用研究进展_宫书林.pdf",
    "affectedPages": [
      "wiki/concepts/选区激光熔化.md",
      "wiki/concepts/高熵合金应用领域.md"
    ],
    "searchQueries": [
      "passive film formation mechanism high entropy alloys",
      "Cr Ni Co enrichment corrosion resistance HEA",
      "potentiodynamic polarization HEA NaCl solution"
    ],
    "options": [
      {
        "label": "Create Page",
        "action": "Create Page"
      },
      {
        "label": "Skip",
        "action": "Skip"
      }
    ],
    "id": "review-2",
    "resolved": true,
    "createdAt": 1779605204057,
    "resolvedAction": "Created: wiki/concepts/-2026-05-24.md"
  },
  {
    "type": "missing-page",
    "title": "张哲峰与田永君学者页面",
    "description": "分析中建议补充高熵合金变形机制研究的核心学者张哲峰 (Z.F. Zhang) 和田永君 (Y.Z. Tian)，二人均来自中国科学院金属研究所，在 CoCrFeMnNi 合金变形行为研究方面有重要贡献。当前 Wiki 仅收录了吕昭平、宫书林等学者，建议创建独立学者页面以完善人物网络。",
    "sourcePath": "C:/Python/产品需求文档AI生成/耐烧蚀高分子/耐烧蚀高分子/raw/sources/随着晶粒细化 CoCrFeMnNi 高熵合金中孪晶行为的转变.pdf",
    "affectedPages": [
      "wiki/entities/CoCrFeMnNi-高熵合金.md",
      "wiki/entities/中国科学院金属研究所.md"
    ],
    "searchQueries": [
      "张哲峰 金属研究所 高熵合金 变形机制",
      "田永君 高熵合金 力学性能 金属所",
      "IMR high entropy alloy deformation mechanism researchers"
    ],
    "options": [
      {
        "label": "Create Page",
        "action": "Create Page"
      },
      {
        "label": "Skip",
        "action": "Skip"
      }
    ],
    "id": "review-3",
    "resolved": true,
    "createdAt": 1779606692776,
    "resolvedAction": "auto-resolved"
  },
  {
    "type": "suggestion",
    "title": "温度 - 晶粒尺寸耦合效应研究",
    "description": "本文献仅研究室温条件下的孪晶行为，但孪晶在低温下通常更易激活。建议后续关注温度与晶粒尺寸的耦合效应 (T-d 图)，以及其他 FCC 结构高熵合金变体（如添加 Al 或 Ti）是否遵循相同的晶粒尺寸阈值。这对理解高熵合金在极端服役条件下的变形行为至关重要。",
    "sourcePath": "C:/Python/产品需求文档AI生成/耐烧蚀高分子/耐烧蚀高分子/raw/sources/随着晶粒细化 CoCrFeMnNi 高熵合金中孪晶行为的转变.pdf",
    "affectedPages": [
      "wiki/concepts/变形孪晶.md",
      "wiki/concepts/临界孪晶应力.md"
    ],
    "searchQueries": [
      "high entropy alloy temperature grain size twinning transition",
      "cryogenic deformation mechanism FCC high entropy alloy",
      "strain rate effect twinning ultrafine grained HEA"
    ],
    "options": [
      {
        "label": "Create Page",
        "action": "Create Page"
      },
      {
        "label": "Skip",
        "action": "Skip"
      }
    ],
    "id": "review-4",
    "resolved": true,
    "createdAt": 1779606692776,
    "resolvedAction": "Created: wiki/queries/--2026-05-24.md"
  }
]