2.2.1: Kinetic Energy

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If an object with mass \(\ m\) is moving with speed \(\ v\), then the amount of kinetic energy that object has is

\(\ K E=\frac{1}{2} m v^{2}\)

If you look at the dimensionality of this equation, you will see that on the right we have mass times length squared divided by time squared. In SI units, that would be kgm²s⁻² , which is the Joule. It is comforting to see that this equation does give us the right units for energy. This equation only works as long as the speed \(\ v\) is a lot less than the speed of light. Once the speed approaches the speed of light, you have to take into account Relativity, and things become more complicated. Why the \(\ \frac{1}{2}\)? The answer may not satisfy you: because that’s what works. You can derive this from forces using a little bit of calculus, but even that derivation requires other definitions that may seem arbitrary. Ultimately, we’ve found that if we use this formula for kinetic energy, rather than something else times \(\ m v^{2}\), the notion of conservation of energy works.

It is also possible to have kinetic energy if you are at rest: you can have rotational kinetic energy if you are rotating. However, at the microscopic level, ultimately this is the same thing. Imagine a ball that’s at rest, but rotating. If you think about each little piece of the ball— each molecule in the ball, if you will— the ones that are not right on the axis of rotation are in fact themselves moving about the center of the ball. The ones closer to the axis are moving slower than the ones farther away. What we call rotational kinetic energy is just a way of summarizing this motion of all of the little pieces of the ball.²

²The formula for rotational kinetic energy is \(\ \frac{1}{2} I \omega^{2}\). \(\ I\) is the moment of inertia; it depends on the mass, size, and geometry of the object. \(\ \omega\) is the angular velocity, in radians per second. It is equal to \(\ 2 \pi\) times the number of rotations per second the rotating object is making. You will read more about \(\ I\) and \(\ \omega\) in Chapter 3.

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