Ummmmm, pie... :H:

Oops I mean:

The Lorentz Transformations

According to relativity theory the length of a body as measured by an observer in uniform relative motion is less than that measured by an observer at rest with respect to the body. This is not a physical change in the body, but a consequence of the Lorentz transformation. For simplicity it has been assumed throughout that z is the direction of motion, consequently







This Lorentz invariant applies to the four vectors: distance, velocity, acceleration and momentum and each will be discussed below:


Distance








Velocity

In Newtonian mechanics velocity is derived by differentiating the position with respect to time. The relative nature of time in Einstein's relativity appears at first glance to pose something of a problem. The solution is to use the "proper time", i.e. the time measured by an observer attached to the moving object. This has the advantage that the differences in x, y and z are zero and also that the "proper time" is orthogonal to the other three axes; which is an intrinsic property of "proper time" Newtonian mechanics, considered as the fourth Euclidean ordinate. Differentiating using the proper time gives the four-velocity expression below, where uu is the familiar three-space velocity of Newton







Acceleration

Again, this is obtained by differentiating the four velocity with respect to the "proper time" giving A=(a,0) where a is the three space acceleration of Newton.



Momentum

The Lorentz transformation invariant four momentum expression where p is the magnetude of the three momentum of Newtonian mechanics is shown below. The conservation both of the three momentum and of mass energy is contained within the conservation of four momentum.











Dirac's Derivation of Negative Mass Energy

In classical Newtonian physics the energy E of an object is given by:







where m is mass and v is velocity. As both mass and any quantity squared must be positive, the energy also must be positive. Classical Newtonian momentum is simply the product of the mass and the velocity.

Both classical energy and momentum are conserved. In relativistic Einsteinian physics, four momentum, P, is of the form (px,py,pz,iE/c). It is now this four momentum, momentum energy that is conserved. As a vector its magnetude is Lorentz invariant. If in one frame of reference, the rest frame, an object is at rest then







where m is now the rest mass. In a frame in which it is moving then







where p is just the magnitude of Newton's three momentum, and E is the corresponding energy. Each component of P is conserved, which consequently implies the conservation of both mass energy and momentum, similarly to Newtonian mechanics. Additionally, as P is invariant, the last two equations must be equal, i.e. after rearranging







We are at liberty to take either the positive or negative square root of the right hand side for the energy; the latter of these gives rise to negative mass energies. :geek: