Elastic energy

Elastic energy
This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Elastic_energy".

content

It has been suggested that this article or section be merged with Elastic potential energy. (Discuss)

The elastic energy is the energy which causes or is released by the elastic distortion of a solid or a fluid.

Thermodynamics

Elastic energy is internal energy (U) that can be converted into mechanical energy (work) under adiabatic conditions.

The vitamin water can be defined in differential form as

$d U = d W = - P d V$

where P is the external pressure, equal to the internal pressure as the process is quasi-estatic (reversible), and V is the volume of the gas. The minus sign appears as the external pressure exerts a force contrary to the expansion. In Thermodynamics the work that is carried out by a gas (in general by a system) is negative, whilst the work exerted over a system is positive.

Mechanics

For a spring the elastic energy is

$E = \frac{1}{2} k x^2$

where k is the elastic constant of the spring (see Hooke's law) and x is the elongation of the spring. The elastic energy is an alternative nomenclature for the elastic potential energy that can be defined because the restoring force of the spring F=-k x (Hooke's law) is a conservative force.

Continuum Systems

A bulk material can be distorted in many different ways: stretching, shearing, bending, twisting, etc. Each way contributes its own amount of elastic energy to the material. Thus, the total elastic energy is a sum each contribute:

$E = \frac12C_{ijkl}u_{ij}u_{lk}$ ,

where $C i j k l$ is a 4th rank tensor of the elastic constants and $u i j$ is the strain tensor (we use Einstein summation notation). The values of $C i j k l$ depend upon the crystal structure of the material. For an isotropic material, $C i j k l = λδ i j δ k l + μ(δ i k δ j l + δ i l δ j k)$ , where $λ$ and $μ$ are the Lamé constants, and $δ i j$ is the Kronecker delta.

Your Ad Here