Why are Lamé parameters different in two dimensions?

Question

The Wikipedia article has a completely separate table for Lamé parameter conversions in the 2D case. Philosophically, why is there even a different table for 2D if these parameters are meant to express intrinsic material qualities? Practically, how does one derive and use the 2D values?

Answer 1

Let me answer here with my own findings, since I am currently working on elasticity of membranes (non-linear membrane model, publications are to appear):

For any isotropic membrane (2D) material, there are two membrane Lamé parameters $(\lambda,\mu)$. We call $\lambda$: first membrane Lamé parameter and $\mu$: second membrane Lamé parameter of that material. They are defined analogously to the classical three dimensional Lamé parameters, by expansion of the stresses close to the natural state/reference configuration:

For any membrane motion (family of time-dependend membrane deformations) starting in the reference configuration, there are two parameters $\lambda$ and $\mu$, such that the derivative of the time-dependend membrane second Piola Kirchhoff stress tensor $S(t)$ with respect to time at $t=0$ can be computed from the derivative of the time-dependend membrane Cauchy-Green deformation tensor $C(t)$ at $t=0$ as follows:

$$ S'(0)= \frac{\lambda}{2}\mathrm{tr}(C'(0))\mathrm{Id}+\mu C'(0). $$

They obtain a physical interpretation by choosing specific membrane motions, like pure shear ($\mathrm{tr}(C'(0))=0$) and pure dilation ($C'(0)=a\cdot\mathrm{Id}$). Then for membranes it turns out that $\mu$ is the membrane shear modulus $g$ and $\lambda+\mu$ is the membrane bulk modulus $k$. (Note that a membrane pure dilation would correspond to an equibiaxial extension in three dimensions.)

Concerning the relation inbetween the 3D and 2D values I think:

Let $\Lambda$ and $M$ denote here the classical 3D Lamé parameters of a given isotropic material (Note the difference in the units: $M,\Lambda$ are in $\tfrac{N}{m^2}$, whereas $\lambda,\mu$ are in $\tfrac{N}{m}$). Then the membrane Lamé parameters for an isotropic elastic film with thickness $d$ in terms of the 3D Lamé parameters of that material are given by $$ \mu =d\cdot M $$ and $$ \lambda =d\cdot\frac{2M\Lambda}{\Lambda+2M} $$

(Any elastic modulus of an isotropic material has its own membrane version, and these can be computed as in the table in Wikipedia. I would also very much like to know the source for that table. Thanks for your question.)