User:Dartonic/sandbox

This article is about the elementary particle of dark matter; Dartons and dartoinc molecules Darton Composition	Elementary particle Interactions	Electromagnetic Symbol	       undefined Theorized	Rick W. Winstead Mass	       Unknown Mean lifetime	Unknown Electric charge	Relative Spin	       Variable

The darton is a type of elementary particle of the electromagnetic field including electromagnetic radiation such as photons, and the force carrier for the electromagnetic force with variable rates of magnetism depending on its paring with with other particles including photons and other dartons.

Like many elementary particles, dartons are currently best explained by principles of quantum mechanics and theorized to exhibit wave–particle duality, exhibiting properties of both waves and particles, depending on its paring and molecular structure. For example, a single dartonic molecule can be paired with a single photon and may be refracted by a lens and exhibit wave interference with itself, and it can behave as a particle with definite and finite measurable position or momentum. The darton's wave and quantum qualities cannot be described by any mechanical model due to their inability to reflect light. Dartons are believed to be the equivalent of photons with the distinct difference of their reflective properties. The modern concept of the darton was developed by Rick W Winstead in early 2015 to explain, using the ontological method, the observations that did not fit the classical definition of dark matter. The benefit of the darton model is that it accounts for the dependence of the photons need for a opposite particle to maintain balance and equilibrum in its expression, and explains the ability of matter and electromagnetic radiation to be in thermal equilibrium. The darton model accounts for anomalous observations, including the properties of black-body radiation, that others (notably Max Planck) had tried to explain using semiclassical models.

In the Standard Model of particle physics, dartons and dartonic particles are a necessary consequence of physical laws having a certain symmetry at every point in spacetime. The intrinsic properties of particles, such as charge, mass, and spin, are determined by this gauge symmetry. The darton concept may led to momentous advances in experimental and theoretical physics, quantum field theory, and the probabilistic interpretation of quantum mechanics. Dartons are yet to be observed due to their non-reflectivity of light; however it stands up to reason and the laws of physics that they are the contrasting element that allows photons to be differentiated from light waves and they are abundantly observed as the essence of shadows, darkness and dark matter.