Quantum mechanics defines our observable environment only in terms of the probabilistic values associated with Schrödinger’s wave equation. However it is extremely difficult to define a set of statements which explains how those probabilities are physically connected to it even though it has held up to rigorous and thorough experimental testing. This may be the … Read more
Quantum entanglement is the name that describes the way that particles can share information and interact with each other regardless of how far apart they are. For example an electron in certain atoms will spontaneously decay after being excited by emitting pairs of polarized photons such that one is aligned horizontally the other vertically. According … Read more
We have shown throughout this blog there would be many theoretical advantages to defining space in terms of a continuous non-quantized field of energy/mass and four *spatial* dimensions instead of four dimensional space-time. One is that it would allow one to understand why a proton and an election have different masses even though the absolute magnitude … Read more
We have postulated throughout this blog that one can derive all the forces of nature by extrapolating the laws governing a three-dimensional environment to one made up of four *spatial* dimensions. If so one should be able to derive the strong force in those terms. The strong force, also known as the strong interaction, is the … Read more
We have shown throughout the this blog that one can derive all the forces of nature by extrapolating the classical laws governing a three-dimensional environment to one made up of four *spatial* dimensions. If so one should be able to define the weak force in those terms. The weak force is responsible for changing to … Read more