Do photons have infinite mass?
We already know that photon do not have rest mass. This is because mass is a property of matter, and light is made up of energy. However, even though photons do not have rest mass, they can still be considered to have mass. For example, the energy of a photon is dependent on its intensity. A high-energy photon has more energy than a low-energy photon. So, a single photon with a higher energy would be considered to have more mass than a single photon with a
Is a photon mass of zero?
The problem is that we don’t know what the photon’s mass is. It’s possible that photons have no mass at all. If this is true, then they would be massless And, according to Einstein’s famous E=mc² equation, mass and energy are interchangeable. This means that a massless particle would have an energy of zero. This is the idea behind the Higgs boson, which was first theorized by Peter Higgs in
Does a photon have infinite mass?
Even though photons are massless, they still have energy and can be subject to the force of gravitational pull. This is because in general relativity, energy and mass are the same thing. Thus, there is no way to differentiate between mass and energy of a particle in the context of curved spacetime. This is because our understanding of spacetime is limited to our eyesight which is restricted to the visible part of the Universe.
Do photon have mass?
The idea of mass is that it is a property of matter and is independent of the motion of the matter. If the matter were to move faster, its mass would still be the same. The energy of motion would be added to the mass of the object, but as the mass is a property of the object, it would not change. This idea was first proposed by Galileo Galilei in the 16th century. He proposed the concept of inertia and described the idea of mass as a property of objects
Does a photon have mass?
No, a photon does not have an invariable rest mass as required by the theory of relativity. The uncertainty in the location of the photon is equivalent to its energy. In other words, the energy of the photon is directly proportional to its uncertainty in position. An energy of zero would mean that the position of the photon is known exactly.