Energy and Momentum in Lorentz Transformations
Michael Fowler, University of Virginia
How Does the Total Energy of a Particle Depend on Speed?
We have a formula for the total energy E = K.E. + rest energy,
so we can see how total energy varies with speed.
The momentum varies with speed as
How Does the Total Energy of a Particle Depend on Momentum?
It turns out to be useful to have a formula for E in terms of p.
hence using p = mv we find
If p is very small, this gives
the usual classical formula.
If p is very large, so c2p2 >> m02c4, the approximate formula is E = cp.
The High Kinetic Energy Limit: Rest Mass Becomes Unimportant!
Notice that this high energy limit is just the energy-momentum relationship Maxwell found to be true for light, for all p. This could only be true for all p if m02c4 = 0, that is, m0 = 0.
Light is in fact composed of “photons”—particles having zero “rest mass”, as we shall discuss later. The “rest mass” of a photon is meaningless, since they’re never at rest—the energy of a photon
is of the form 0/0, since m0 = 0 and v = c, so “m” can still be nonzero. That is to say, the mass of a photon is really all K.E. mass.
For very fast electrons, such as those produced in high energy accelerators, the additional K.E. mass can be thousands of times the rest mass. For these particles, we can neglect the rest mass and take E = cp.
Transforming Energy and Momentum to a New Frame
We have shown
Notice we can write this last equation in the form
That is to say, depends only on the rest mass of the particle and the speed of light. It does not depend on the velocity of the particle, so it must be the same—for a particular particle—in all inertial frames.
This is reminiscent of the invariance of , the interval squared between two events, under the Lorentz transformations. One might guess from this that the laws governing the transformation from E, p in one Lorentz frame toE′, p′ in another are similar to those for x,t. We can actually derive the laws for E, p to check this out.
As usual, we consider all velocities to be parallel to the x-axis.
We take the frame S' to be moving in the x-direction at speed v relative to S.
Consider a particle of mass m0 (rest mass) moving at u′ in the x′ direction in frame S', and hence at u along x in S, where
The energy and momentum in S' are
and in S:
from which it is easy to show that
Similarly, we can show that
These are the Lorentz transformations for energy and momentum of a particle—it is easy to check that
Photon Energies in Different Frames
For a zero rest mass particle, such as a photon, E = cp, E2 – c2p2 = 0 in all frames.
Since E = cp, E′ = cp′ we also have
Notice that the ratios of photon energies in the two frames coincides with the ratio of photon frequencies found in the Doppler shift. As we shall see when we cover quantum mechanics, the photon energy is proportional to the frequency, so these two must of course transform in identical fashion. But it’s interesting to see it come about this way. Needless to say, relativity gives us no clue on what the constant of proportionality (Planck’s constant) is: it must be measured experimentally. But the same constant plays a role in all quantum phenomena, not just those concerned with photons.