Table 5.2  Elastic constants for isotropic materials at room temperaturet.

 Material  Composition  Modulus of  Poisson's  Shear Modulus^  Lame Constant A  Bulk Modulus k
 Elasticity E Y  Ratio v
 6                            s
 10 psi  GPa  10 psi  GPa    10 psi  GPa      10 psi  GPa
 Aluminum  Pure and alloy  9.9-11.4  68.2-78.5  0.32-0.34  3.7-3.85  25.5-26.53  6.7-9.1  46.2-62.7  9.2-11.7  63.4-80.6
 Brass  60-70% Cu, 40-30% Zn  14.5-15.9  99.9-109.6  0.33-0.36  5.3-6.0  36.6-41.3  10.6-15.0  73.0-103.4  14.1-19.0  97.1-130.9
 Copper  17-18  117-124  0.33-0.36  5.8-6.7  40.0-46.2  12.4-19.0  85.4-130.9  163.3-21.5  112.3-148.1
 Iron, cast  2.7-3.6% C  13-21  90-145  0.21-0.30  5.2-8.2  35.8-56.5  3.9-12.1  26.9-83.4  7.4-17.6  51.0-121.3
 Steel  Carbon and low alloy  5.4-16.6  106.1-114.4  0.34  6.0  41.3  12.2-13.2  84.1-90.9  16.2-17.2  111.6-118.5
 Stainless steel  18% Cr, 8% Ni  28-30  193-207  0.30  10.6  73.0  16.2-17.3  111.6-119.2  23.2-24.4  160.5-168.1
 Titanium  Pure and alloy  15.4-16.6  106.1-114.4  0.34  6.0  41.3  12.2-13.2  84.1-90.9  16.2-17.2  111.6-118.5
 Glass  Various  7.2-11.5  49.6-79.2  0.21-0.27  3.8-4.7  26.2-32.4  2.2-5.3  15.2-36.5  4.7-8.4  32.4-57.9
 Methyl methacrylate  0.35-0.5  2.41-3.45  --  --  --  --  --  --  --
 Polyenthylene  0.02-0.055  0.14-0.38
                                 t        t       t        t
 Rubber  0.00011-  0.00076-  0.50  0.00004-  0.00028-  00  90  oc  00
 0.00060  0.00413  0.00020  0.00138

 t As v approaches 0.5 the ratio of k/Ey and A/^u -» ». The actual value of k and A for some rubbers may be close to the values of
 steel.
 $ Partly from "an Introduction to the Mechanics of Solids," S.H. Crandall and N.C. Dahl, (Eds.), Mcgraw-Hill, 1959. (Used
 with permission of McGraw-Hill Book Company.)