Young's modulus

Young's Modulus, or lambda E, is an elastic modulus is a measure of the stiffness of a material. It is used extensively in quantitative seismic interpretation, rock physics, and rock mechanics. It is defined as the ratio of uniaxial stress to uniaxial strain when linear elasticity applies. It is analogous to the proportionality constant in Hooke's Law $$F=-kx$$.

Definition

 * $$\mathrm{Young's}\ \mathrm{modulus} = \frac{\mathrm{longitudinal}\ \mathrm{stress}}{\mathrm{longitudinal}\ \mathrm{strain}}$$


 * $$E = \frac{F / W^2}{\Delta L / L}$$

Where W2 is the cross-sectional area of the material (see figure).

In terms of VP and VS

 * $$E=\frac{\rho V_\mathrm{S}^2\left ( 3V_\mathrm{P}^2-4V_\mathrm{S}^2 \right )}{V_\mathrm{P}^2-V_\mathrm{S}^2}$$

Here's a function you can paste into Excel to compute Young's modulus (see Using equations in Excel):

=rho*Vs^2*(3*Vp^2-4*Vs^2)/(Vp^2-Vs^2)

And here is the same code for definition as a function in VBA:

Public Function Youngs(Vp As Double, Vs As Double, rho As Double) As Double Youngs = rho * Vs ^ 2 * (3 * Vp ^ 2 - 4 * Vs ^ 2) / (Vp ^ 2 - Vs ^ 2) End Function

Other expressions
E can also be expressed in terms of the first Lamé parameter &lambda; and shear modulus &mu;:


 * $$E = \frac{\mu(3\lambda+2\mu)}{\lambda+\mu}$$

The simplest expression casts E in terms of bulk modulus K and shear modulus &mu;:


 * $$E = \frac{9K\mu}{3K+\mu}$$

The (E, &lambda;) problem
The other elastic moduli are not pretty when expressed in terms of E and &lambda;:


 * $$\mu = \frac14 \left( -3\lambda + E \pm \sqrt{9\lambda^2 + 2\lambda E + E^2} \right) $$


 * $$ K = \frac16 \left( 3\lambda + E \pm \sqrt{9\lambda^2 + 2\lambda E + E^2} \right) $$


 * $$\nu = \frac{1}{4\lambda} \left( -\lambda - E \pm \sqrt{9\lambda^2 + 2\lambda E + E^2} \right) $$


 * $$ M = \frac12 \left( -\lambda + E \pm \sqrt{9\lambda^2 + 2\lambda E + E^2} \right) $$

What is this quantity $$\sqrt{9\lambda^2 + 2\lambda E + E^2}$$ ?