Why doesn't light carry momentum?
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Answers
Answer:
light loses momentum by lowering its frequency rather than by lowering its speed. The fact that light carries momentum has profound effects on particle interactions because of the law of conservation of momentum
Answer:
Light indeed carries energy and accomplishes this without having any mass. The Einstein equation that you are probably referring to is E = mc2. This equation is actually a special case of the more general equation:
E2 = p2c2 + m2c4
In the above equation, E is the total energy of the particle, p is the momentum of the particle (which is related to its motion), c is the speed of light, and m is the mass of the particle. This equation can be derived from the relativistic definitions of the energy and momentum of a particle. The above equation tells us that the total energy of a particle is a combination of its mass energy and its momentum energy (which is not necessarily related to its mass). When a particle is at rest (p = 0), this general equation reduces down to the familiar E = mc2. In contrast, for a particle with no mass (m = 0), the general equation reduces down to E = pc. Since photons (particles of light) have no mass, they must obey E = pc and therefore get all of their energy from their momentum.
Now there is an interesting additional effect contained in the general equation. If a particle has no mass (m = 0) and is at rest (p = 0), then the total energy is zero (E = 0). But an object with zero energy and zero mass is nothing at all. Therefore, if an object with no mass is to physically exist, it can never be at rest. Such is the case with light. Furthermore, if the object travels at some speed v that is less than the universal speed limit c, we can always choose a reference frame traveling along with the object so that the object will be at rest in this reference frame. Therefore, an object that can never be at rest must always travel at the universal speed limit c, because this speed has the interesting property that once an object goes a speed c in one reference frame, it goes the speed c in all reference frames. In summary, all objects with no mass can never be at rest and must travel at speed c in all reference frames. Light is such an object, and the universal speed limit c is named the speed of light in its honor. But light is not the only massless object. Gluons and the hypothetical gravitons are also massless, and therefore travel at speed c in all frames.