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6: Yield and Fracture

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    • 6.1: Yield and Plastic Flow
      This page explores the concept of yielding in materials, emphasizing its dependence on molecular mobility and processing optimization. It compares polystyrene types, discusses yield criteria (Tresca and von Mises), and examines factors like hydrostatic pressure, temperature, and strain rates affecting yield behavior. Additionally, it covers yield strength in polycarbonate, plastic deformation, wire drawing, slip-line theory, and relationships between stress and hardness.
    • 6.2: Dislocation Basis of Yield and Creep
      This page explores the role of dislocations in crystalline materials, emphasizing their influence on yield strength and deformation. It covers dislocation types, their movement, and interactions leading to creep and fracture. Key concepts include the transition of dislocation characters, critical resolved shear stress, and dislocation multiplication mechanisms like the Frank-Read source.
    • 6.3: Statistics of Fracture
      This page emphasizes the statistical analysis of fracture in high-strength materials, crucial for design related to human safety. It introduces key statistical measures, distribution functions (normal and Weibull), and the importance of repeated measurements to reduce uncertainty in strength values. The t-distribution is highlighted for small samples, and connections between specimen volume and failure probability are discussed.
    • 6.4: Introduction to Fracture Mechanics
      This page discusses the cost and implications of material fractures, emphasizing fracture mechanics and safety in engineering design. It reviews historical incidents like the DeHavilland Comet and Aloha Airlines Flight 243, illustrating challenges in aircraft design against catastrophic failures due to cracks. Key concepts include stress intensity factors, ASTM standards for fracture toughness, and the effects of material properties such as grain size and temperature on ductility and brittleness.
    • 6.5: Fatigue
      This page discusses material fatigue leading to failure from repeated loading, focusing on crack initiation and growth patterns, tools like the S-N curve and Goodman diagram, and the limitations of Miner's Law in estimating cumulative damage. It also introduces Paris law for crack growth rates linked to stress intensity, underscoring the need for safety in engineering.

    Thumbnail: Ductile failure of a specimen strained axially. (CC BY-SA 3.0; BradleyGrillo via Wikipedia)

    This page titled 6: Yield and Fracture is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by David Roylance (MIT OpenCourseWare) via source content that was edited to the style and standards of the LibreTexts platform.