Difference between revisions of "Forest UCM EnergyIntPart"
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:<math> v_1^2 = \left (v_1^{\;\prime} \right )^2 + \left ( v_2^{\;\prime} \right )^2 + 2 \vec{v}_1^{\;\prime} \cdot \vec{v}_2^{\;\prime} </math> | :<math> v_1^2 = \left (v_1^{\;\prime} \right )^2 + \left ( v_2^{\;\prime} \right )^2 + 2 \vec{v}_1^{\;\prime} \cdot \vec{v}_2^{\;\prime} </math> | ||
− | compare the above conservation of momentum | + | compare the above conservation of momentum equation with the conservation of energy equation |
:<math> v_1^2 = \left (v_1^{\;\prime} \right )^2 + \left ( v_2^{\;\prime} \right )^2</math> | :<math> v_1^2 = \left (v_1^{\;\prime} \right )^2 + \left ( v_2^{\;\prime} \right )^2</math> |
Revision as of 13:12, 28 September 2014
Energy of Interacting particles
Translational invariance
One potential for Both Particles
Both forces from same potential
just take appropriate derivative
Total work given by one potential
Elastic Collisions
Definition
BOTH Momentum and Energy are conserved in an elastic collision
- Example
Consider two object that collide elastically
- Conservation of Momentum
- Conservation of Energy
When the initial and final states are far away fromthe collision point
- arbitrary constant
Example
Consider an elastic collision between two equal mass objecs one of which is at rest.
- Conservation of momentum
- Conservation of Energy
- Square the conservation of momentum equation
compare the above conservation of momentum equation with the conservation of energy equation
and you conclude that