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Yield stress as a function of temperature for NiAl, Ni Al, and several commercial superaUoys where 001 is the paraHel-to-tensile axis for single crystals and . See text. To convert MPa to psi, multiply by 145.

Yield stress as function of temperature of the hypoeutectic Ti-Si7.5-All alloy and die unidirectionally solidified eutectic Ti-Ti5Si3 composite. In comparison the yield stress curve of the Ti5Si3 compound is plotted in the diagram.

Yield stress c 5 and Young modulus E25 for glassy networks, e 10 2 min

Yield stress dependence on temperature under compression for various Cr-Re alloys.

Yield stress for several engineering materials. .

Yield stress function Y

Yield stress in dependence on content of softening agent for different materials .

Yield stress in uniaxial compression plotted in relation to average lamellae thickness. Compression rate 0.000055s . The dashed line is the best fit of Eq. fi-om Xu and Argon

Yield stress normalized by the elastic shear modulus plotted against a size scale parameter illustrating the six orders of magnitude of stress levels and ten orders of magnitude of size related to plastic behavior of single crystal metals

Yield stress normalized to temperature as a function of logarithmic strain rate for polycarbonate. After Bauwens-Crowet and co-workers with permission.

Yield stress of 25 vol alumina suspensions

Yield stress of alumina suspensions at their lEP as a function of particle size. The best fit line has a slope of —2.01, correlating quite well with the predicted inverse square particle size dependence as per Equation .

Yield stress of BaTi0.i silicone oil suspension as a function of temperature. The particle volume fraction is 0,20. Reproduced with permission from T. Hao, A, Kawai, and F. Ikazaki, Langmuir, 163058.

Yield stress of carbon fiber polycarbonate composite vs. aging time in boiling water. Adapted, by permission, from Nofal M M, Zihlif A M, Ragosta G, Martuscelli E, Polym. Composites, 17, No.5, 1996, 705-9.

Yield stress of carbon fiber polycarbonate composite vs. aging time in boiling water. Adapted, by permission. Irom Nofal M M, Zihlif A M, Ragosta G, MartusceUi E, Polym. Composites, 17, No.5, 1996, 705-9.1

Yield stress of cast films

Yield stress of composite particle with 1,3-butylene glycol dimethacrylate butyl acrylate copolymer core and titanium hydroxide and phthalocyanine blue pigment shell dispersed in silicone oil vs. the

Yield stress of HDPE as a function of crystal thickness and compression rate

Yield stress of HIPS, expressed as a fraction of the yield stress of PS, as a function of rubber phase volume. E ata obtained by Oxboroiigh and Bowden

Yield stress of PMMA and various CMIMx copolymers versus temperature

Yield stress of PMMA and various CMlMx copolymers versus temperatiue 0.05

Yield stress of PMMA, MGIM36 and MG1M76 copolymers, versus

Yield stress of PMMA, MGIM36 and MGIM76 copolymers, versus

Yield stress of polyethylene as a function of crystal thickness .

Yield stress of polymethyl methacrylate as a function of strain rate, o, compression at 23 C A, tension at 90 C , tension at 60 C. Curves represent the best theoretical fit .



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