Work and Energy| Work and Kinetic Energy Theorem
Consider the motion in 1D and the kinematics equation, $v_{fx}^2 = v_{ix}^2 + 2a_x \Delta x$, and Newton's 2nd Law with constant acceleration in one dimension, $\sum F_x = m a_x$. A simple substitution, and minor rearrangements, of the acceleration from the 2nd law into the kinematics equation yields:
$\frac{1}{2}m v_{fx}^2 - \frac{1}{2}m v_{ix}^2 = \sum F_x \Delta x$
It appears that forces acting over a distance changes the velocity of objects according to the equation above. As it turns out, this manipulation of equations will be of great benefit in analyzing the motion of objects, so we define new terms for the expressions shown in the above equation.
Linear Kinetic Energy (K): $\frac{1}{2}m v^2$.
Work (W): $F_x \Delta x$.
Using our newly defined terms, we now can write what we call, the Work-Kinetic Energy theorem as:
$K_f - K_i = \sum W$
This expression lets you see the heart of the Work-Kinetic Energy theorem, namely that a system's change in energy is due to work from external forces performed on the system. The theorem is often rearranged so that it can be interpreted as: take the initial kinetic energy of the system and add the net work acting on the system and this is equal to the final kinetic energy of the system.
$K_i + \sum W = K_f$
**Note: K and W are scalar quantities! The above arguments are shown in one dimension. Continue reading further in this section to learn how to generalize if our forces, displacements, or velocities are in more than one dimension.
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