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Yield strength of pure HDPE, PET HDPE conventional composite and MRC with different

Yield strength of rPET OMMT nanocomposites at different concentrations of OMMT. Reprodnced with permission from R. Merijs Meri,

Yield strength of several US austenitic steels

Yield strength per density of various hardened materials.

Yield strength specific gravity of unfilled poly.

Yield strength vs. temperature for Asahi Glass Fluon C-88 series ETFE resins ,

Yield strength-Kjscc dependence for LASs for transgranular, intergranular, and mixed SCC .

Yield strengths from flexural tests are plotted against strain rates at the surface of the samples. Tests were performed on polymers A, B, and E test temperature 23 C. The slope of the three lines correspond to similar activation volumes

Yield strengths from flexural tests are plotted against the densities of the polymers. The annealed samples were noticeably stronger than the quenched ones of similar density. Rigidity

Yield strengths from tensile tests at 23 C are plotted against the glass transition temperatures of the five polymers result of extrapolated stress-strain-curve

Yield strengths in ihree-point bend tests of highly filled composites of poly and silica particles treated with methylsilane and octylsilane coupling agents to varying degrees of surface coverage vs. work of adhesion measured independently using IGC. Redrawn from ref. .

Yield strengths in three-point bend tests of highly filled composites of polyfvinyl butyral and silica particles treated with methylsilane and octylsilane coupling agents to varying degrees of surface coverage vs. work of adhesion measured independently using IGC. Redrawn from ref. .

Yield strengths of the five polymers are plotted against 1 MC that is the inverse molecular mass between crosslinks. The diamond represents polymer E. Test temperature

Yield stress .

Yield stress against stem length for polyethylenes at —2

Yield stress against the electric field for various mixed suspensions containing humidified glass beads. d i is the volume fraction of small particles 3880

Yield stress and critical dilatational stress required for crack nucleation in PEEK

Yield stress and gel strength as a function of shear rate for a sample that has been allowed to sit for several hours . This behavior is related to the structure changes observed in

Yield stress and gel strength as a function of shear rate. This oil sands fine tailings sample was sheared in rheometer to disrupt the floe structure before the run. The hysteresis in the curve is indicative of the thixotropy or shear thinning behavior of the suspension. This behavior is related to the structure changes observed using microscopy .

Yield stress and plastic flow stress versus temperature

Yield stress as a function of Brij 30 concentration for 20 wt neutral alumina suspensions in silicone oil, with varying water contents. Nondried, 3.47 wt 568

Yield stress as a function of dispersant concentration for different cements. The yield stress begins to increase with dispersant concentration and then decreases. This is due to the originally smaller number of negatively charged sites that increases with the dispersant to match the number of positively charged sites

Yield stress as a function of imposed hydrostatic pressure for polyethylene and polypropylene. Data from Ref 28. o, polyethylene, , Pol5rpropylene.

Yield stress as a function of imposed hydrostatic pressure for polyethylene and polypropylene. Data from Ref 28. O, polyethylene, , Polypropylene.

Yield stress as a function of pH for kaolinite alone.



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