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3.35 Fracture and Fatigue (MIT) 3.35 Fracture and Fatigue (MIT)

Description

Investigation of linear elastic and elastic-plastic fracture mechanics. Topics include microstructural effects on fracture in metals, ceramics, polymers, thin films, biological materials and composites, toughening mechanisms, crack growth resistance and creep fracture. Also covered: interface fracture mechanics, fatigue damage and dislocation substructures in single crystals, stress- and strain-life approach to fatigue, fatigue crack growth models and mechanisms, variable amplitude fatigue, corrosion fatigue and case studies of fracture and fatigue in structural, bioimplant, and microelectronic components. Investigation of linear elastic and elastic-plastic fracture mechanics. Topics include microstructural effects on fracture in metals, ceramics, polymers, thin films, biological materials and composites, toughening mechanisms, crack growth resistance and creep fracture. Also covered: interface fracture mechanics, fatigue damage and dislocation substructures in single crystals, stress- and strain-life approach to fatigue, fatigue crack growth models and mechanisms, variable amplitude fatigue, corrosion fatigue and case studies of fracture and fatigue in structural, bioimplant, and microelectronic components.

Subjects

Linear elastic | Linear elastic | elastic-plastic fracture mechanics | elastic-plastic fracture mechanics | Microstructural effects on fracture | Microstructural effects on fracture | Toughening mechanisms | Toughening mechanisms | Crack growth resistance | Crack growth resistance | creep fracture | creep fracture | Interface fracture mechanics | Interface fracture mechanics | Fatigue damage | Fatigue damage | dislocation substructures | dislocation substructures | Variable amplitude fatigue | Variable amplitude fatigue | Corrosion fatigue | Corrosion fatigue | experimental methods | experimental methods | microstructural effects | microstructural effects | metals | metals | ceramics | ceramics | polymers | polymers | thin films | thin films | biological materials | biological materials | composites | composites | single crystals | single crystals | stress-life | stress-life | strain-life | strain-life | structural components | structural components | bioimplant components | bioimplant components | microelectronic components | microelectronic components | case studies | case studies

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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3.35 Fracture and Fatigue (MIT) 3.35 Fracture and Fatigue (MIT)

Description

Investigation of linear elastic and elastic-plastic fracture mechanics. Topics include microstructural effects on fracture in metals, ceramics, polymers, thin films, biological materials and composites, toughening mechanisms, crack growth resistance and creep fracture. Also covered: interface fracture mechanics, fatigue damage and dislocation substructures in single crystals, stress- and strain-life approach to fatigue, fatigue crack growth models and mechanisms, variable amplitude fatigue, corrosion fatigue and case studies of fracture and fatigue in structural, bioimplant, and microelectronic components. Investigation of linear elastic and elastic-plastic fracture mechanics. Topics include microstructural effects on fracture in metals, ceramics, polymers, thin films, biological materials and composites, toughening mechanisms, crack growth resistance and creep fracture. Also covered: interface fracture mechanics, fatigue damage and dislocation substructures in single crystals, stress- and strain-life approach to fatigue, fatigue crack growth models and mechanisms, variable amplitude fatigue, corrosion fatigue and case studies of fracture and fatigue in structural, bioimplant, and microelectronic components.

Subjects

Linear elastic | Linear elastic | elastic-plastic fracture mechanics | elastic-plastic fracture mechanics | Microstructural effects on fracture | Microstructural effects on fracture | Toughening mechanisms | Toughening mechanisms | Crack growth resistance | Crack growth resistance | creep fracture | creep fracture | Interface fracture mechanics | Interface fracture mechanics | Fatigue damage | Fatigue damage | dislocation substructures | dislocation substructures | Variable amplitude fatigue | Variable amplitude fatigue | Corrosion fatigue | Corrosion fatigue | experimental methods | experimental methods | microstructural effects | microstructural effects | metals | metals | ceramics | ceramics | polymers | polymers | thin films | thin films | biological materials | biological materials | composites | composites | single crystals | single crystals | stress-life | stress-life | strain-life | strain-life | structural components | structural components | bioimplant components | bioimplant components | microelectronic components | microelectronic components | case studies | case studies

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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3.35 Fracture and Fatigue (MIT) 3.35 Fracture and Fatigue (MIT)

Description

Investigation of linear elastic and elastic-plastic fracture mechanics. Topics include microstructural effects on fracture in metals, ceramics, polymers, thin films, biological materials and composites, toughening mechanisms, crack growth resistance and creep fracture. Also covered: interface fracture mechanics, fatigue damage and dislocation substructures in single crystals, stress- and strain-life approach to fatigue, fatigue crack growth models and mechanisms, variable amplitude fatigue, corrosion fatigue and case studies of fracture and fatigue in structural, bioimplant, and microelectronic components. Investigation of linear elastic and elastic-plastic fracture mechanics. Topics include microstructural effects on fracture in metals, ceramics, polymers, thin films, biological materials and composites, toughening mechanisms, crack growth resistance and creep fracture. Also covered: interface fracture mechanics, fatigue damage and dislocation substructures in single crystals, stress- and strain-life approach to fatigue, fatigue crack growth models and mechanisms, variable amplitude fatigue, corrosion fatigue and case studies of fracture and fatigue in structural, bioimplant, and microelectronic components.

Subjects

Linear elastic | Linear elastic | elastic-plastic fracture mechanics | elastic-plastic fracture mechanics | Microstructural effects on fracture | Microstructural effects on fracture | Toughening mechanisms | Toughening mechanisms | Crack growth resistance | Crack growth resistance | creep fracture | creep fracture | Interface fracture mechanics | Interface fracture mechanics | Fatigue damage | Fatigue damage | dislocation substructures | dislocation substructures | Variable amplitude fatigue | Variable amplitude fatigue | Corrosion fatigue | Corrosion fatigue | experimental methods | experimental methods | microstructural effects | microstructural effects | metals | metals | ceramics | ceramics | polymers | polymers | thin films | thin films | biological materials | biological materials | composites | composites | single crystals | single crystals | stress-life | stress-life | strain-life | strain-life | structural components | structural components | bioimplant components | bioimplant components | microelectronic components | microelectronic components | case studies | case studies

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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TALAT Lecture 2403: Applied Fracture Mechanics TALAT Lecture 2403: Applied Fracture Mechanics

Description

This lecture demonstrates how to teach the principles and concepts of fracture mechanics as well as provide recommendations for practical applications; it provides necessary information for fatigue life estimations on the basis of fracture mechanics as a complementary method to the S-N concept. Background in engineering, materials and fatigue is required. This lecture demonstrates how to teach the principles and concepts of fracture mechanics as well as provide recommendations for practical applications; it provides necessary information for fatigue life estimations on the basis of fracture mechanics as a complementary method to the S-N concept. Background in engineering, materials and fatigue is required.

Subjects

aluminium | aluminium | aluminum | aluminum | european aluminium association | european aluminium association | EAA | EAA | Training in Aluminium Application Technologies | Training in Aluminium Application Technologies | training | training | metallurgy | metallurgy | technology | technology | lecture | lecture | design | design | fatigue | fatigue | fracture | fracture | notch toughness | notch toughness | brittle fracture | brittle fracture | performance level | performance level | toughness | toughness | crack size | crack size | stress level | stress level | stress intensity factors | stress intensity factors | deformation | deformation | crack tip | crack tip | superposition | superposition | linear-elastic fracture mechanics | linear-elastic fracture mechanics | KIc | KIc | ASTM-E399 test method | ASTM-E399 test method | elastic-plastic fracture mechanics | elastic-plastic fracture mechanics | crack opening displacement | crack opening displacement | test method BS 5762 | test method BS 5762 | R-curves | R-curves | ASTM-E561 | ASTM-E561 | ASTM-E813 | ASTM-E813 | ASTM-E1152 | ASTM-E1152 | J-R curves | J-R curves | JIc | JIc | free surface correction Fs | free surface correction Fs | crack shape correction Fe | crack shape correction Fe | finite plate dimension correction Fw | finite plate dimension correction Fw | correction factors for stress gradient Fg | correction factors for stress gradient Fg | crack geometry | crack geometry | evaluation | evaluation | welded coverplate | welded coverplate | web stiffener | web stiffener | corematerials | corematerials | ukoer | ukoer

License

http://creativecommons.org/licenses/by-nc-sa/2.0/uk/

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TALAT Lecture 2403: Applied Fracture Mechanics

Description

This lecture demonstrates how to teach the principles and concepts of fracture mechanics as well as provide recommendations for practical applications; it provides necessary information for fatigue life estimations on the basis of fracture mechanics as a complementary method to the S-N concept. Background in engineering, materials and fatigue is required.

Subjects

aluminium | aluminum | european aluminium association | eaa | talat | training in aluminium application technologies | training | metallurgy | technology | lecture | design | fatigue | fracture | notch toughness | brittle fracture | performance level | toughness | crack size | stress level | stress intensity factors | deformation | crack tip | superposition | linear-elastic fracture mechanics | kic | astm-e399 test method | elastic-plastic fracture mechanics | crack opening displacement | test method bs 5762 | r-curves | astm-e561 | astm-e813 | astm-e1152 | j-r curves | jic | free surface correction fs | crack shape correction fe | finite plate dimension correction fw | correction factors for stress gradient fg | crack geometry | evaluation | welded coverplate | web stiffener | corematerials | ukoer | Engineering | H000

License

Attribution-Noncommercial-Share Alike 2.0 UK: England & Wales Attribution-Noncommercial-Share Alike 2.0 UK: England & Wales http://creativecommons.org/licenses/by-nc-sa/2.0/uk/ http://creativecommons.org/licenses/by-nc-sa/2.0/uk/

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