To develop this problem it is necessary to apply the concepts related to the uni-axial deflection of bodies.
From the expression of Hooke's law we have to
[tex]\sigma = E\epsilon[/tex]
Where,
E= Young's modulus
[tex]\epsilon =[/tex] The strain
And substituting P/A for stress and [tex]\delta/L[/tex] for strain gives that
[tex]\frac{P}{A} = E\frac{\delta}{L}[/tex]
Where,
P = Force
A = Area
L = Length
Therefore this can be re-arranged to give
[tex]\delta = \frac{PL}{AE}[/tex]
If we want to calculate the deformation per unit area then we can also rewrite the equation as
[tex]\frac{delta}{L} = \frac{P}{AE}[/tex]
Replacing with our values we have to
[tex]\frac{delta}{L} = \frac{14400}{(\pi/4 (11.1*10^{-3})^2)(100*10^9)}[/tex]
[tex]\frac{delta}{L} = 0.001488[/tex]
Therefore the posion ratio would be
[tex]\upsilon = \frac{\frac{\delta_{decreased}}{d}}{\frac{\delta_l}{L}}[/tex]
[tex]\upsilon = \frac{\frac{7*10^{-3}}{11.1}}{0.001488}[/tex]
[tex]\upsilon = 0.4238[/tex]
Therefore the Poisson's ratio for this material is 0.4238
