brupenney said:Thanks guys. Taking the case of a neutron moving with velocity v, would its radius in the direction of v shorten while its radius perpendicular to v increases? It seems if this is so, then the neutron would assume an ellipsoid shape, more specifically an oblate spheroid shape, until it would become a disk at some point. Is this correct?
bcrowell said:The radius perpendicular to the direction of motion is unchanged.
PAllen said:Yes, such appearance as a disk has been dubbed a 'pancake', and, I believe Richard Feynman was the first to describe that the collision data for energetic electrons and nucleons could be explained on the assumption that the nucleon appeared as a pancake to the electron. This modelling assumption was part of his famous parton research which explained key behavior of the quark model of nucleons. Without modelling the nucleon as a pancake, the collision data could not be explained.
Most physicists these days don't use the relativistic mass convention that you're using, but anyway, the density of mass-energy is higher as seen in the frame where the neutron is moving.brupenney said:Thanks Ben. How then does the mass increase without the perpendicular radius increasing?
No, that's not true.brupenney said:I am assuming the neutron is the most dense unit of mass possible.
brupenney said:Hi Ben. Tks for replying. Is the mass expansion and length contraction real then. I thought it was, from the observer's viewpoint. And what is more dense than a neutron?
Acceleration causes a change in the velocity of a mass, which can result in a change in its shape. This is because the force of acceleration can cause the mass to stretch or compress, depending on the direction of the force.
Yes, the shape of a mass can change during constant acceleration. This is because even though the velocity may be changing at a constant rate, the force of acceleration can still cause the mass to stretch or compress.
When a mass accelerates in a circular motion, it experiences a centripetal force that pulls it towards the center of the circle. This force can cause the mass to deform into a circular shape, depending on the strength of the force and the elasticity of the mass.
In theory, it is possible for the shape of a mass to remain constant while it accelerates. This would require the force of acceleration to be evenly distributed throughout the mass, so that no part of it experiences a greater force than any other part. However, in most cases, some level of deformation will occur during acceleration.
According to Einstein's theory of relativity, as an object approaches the speed of light, its mass increases and its length contracts. This means that the shape of the mass can also change, becoming more elongated in the direction of motion. However, this effect is only noticeable at speeds close to the speed of light and is not significant at everyday speeds.