Mechanical Behavior of Materials |
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Page 205
... martensite transformation ) initiates at an appropriate undercooling ( the martensite start temperature , M , ) and the reaction is essentially complete at a lower temperature ( M ,, the martensite finish temperature ) . During the ...
... martensite transformation ) initiates at an appropriate undercooling ( the martensite start temperature , M , ) and the reaction is essentially complete at a lower temperature ( M ,, the martensite finish temperature ) . During the ...
Page 206
... martensite transformation . Although both of these structural features contribute to the strength of virgin martensite , it has been shown that by far the greatest strengthening contribution is made by interstitial carbon . This ...
... martensite transformation . Although both of these structural features contribute to the strength of virgin martensite , it has been shown that by far the greatest strengthening contribution is made by interstitial carbon . This ...
Page 661
... martensite embrittlement can be monitored by measuring the impact energy . This energy is plotted vs. tempering temperature for a 3.5 Ni , 1.7 Cr , 0.3 C steel . The energy shows a broad minimum for tempering temperatures in the 200-425 ...
... martensite embrittlement can be monitored by measuring the impact energy . This energy is plotted vs. tempering temperature for a 3.5 Ni , 1.7 Cr , 0.3 C steel . The energy shows a broad minimum for tempering temperatures in the 200-425 ...
Contents
Elastic Behavior | 46 |
Plastic Deformation in Single and Polycrystalline | 137 |
Strengthening of Crystalline Materials | 162 |
Copyright | |
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alloys applied approximately associated atomic behavior bonding brittle caused composite considerations considered containing crack crack tip creep creep rate critical crystal curve cyclical decreases deformation depends described determined developed diffusion direction discussed dislocation displacement distance ductile effect elastic embrittlement energy engineering example failure fatigue fiber FIGURE flow force fraction fracture function given glass grain boundaries greater growth hardening high-temperature higher illustrated increases initial lead length less load material matrix maximum mechanism metals microscopic Mode normal observed obstacles obtained occurs particle phase plane plastic polymers produce propagation reduced region relative resistance result schematically shear shear stress shown in Fig shows similar slip slip plane solid Stage steel strain rate strength strengthening structure surface takes place temperature tensile toughness transition typically values variation void volume yield