What is Matter?

We easily describe what matter is like since matter is just the stuff that makes up all objects and so each object has a single dimension of mass. Objects are made of matter and that matter is finitely divisible into the atoms, electrons, protons, and neutrons of our microscopic universe. Unlike the equally intuitive notion of space, though, matter does not suffer from being infinitely divisible. The hard stop for matter is the electron, which is indivisible, and the quark pair, since a quark pair along with its gluon particle exchange would take the energy of the universe to separate.

Both protons and neutrons are made of three quarks, or really two quark pairs and bonding gluons, that is it as far as matter is concerned. In matter time, the universe is mostly boson matter and the smallest boson particle is the gaechron and gaechron are very much smaller than other matter particles. But even atoms are very small and their numbers are very large. A kilogram of hydrogen is 6e26 atoms and matter is therefore a virtual infinity of particles.

Although we experience matter as the single dimension of intensity or amplitude squared, objects actually exist as matter wave amplitudes that have both phase and oscillation of their amplitude. This means that a particle can exist as matter wave amplitude among any number of world timelines along that matter wave, but that particle will only be realized as intensity on one particular timeline. Our universe is mostly space with only a relatively small amount of fermionic matter, like hydrogen, on the order of one atom of hydrogen per cubic meter of space. However, in matter time most of the matter in the universe is bosonic and is not in the form of fermions. In fact, there is about eleven million times more bosonic than fermionic matter in the universe and so it turns out that shrinking bosonic matter largely drives force and action and force and action are how the universe evolves.

The small amount of baryonic matter, the protons and neutrons of fermionic matter, stands in contrast to the overwhelming amount of bosonic matter. So where are the bosons hiding? In plain sight of course, or maybe plainly out of sight. Although it is tempting to imagine that space is filled with a quantum boson foam from which fermions seethe into and out of existence, that implies that space has an existence independent of the action of matter in time. It is much better to assume space is a projection of matter action and that there is a universal matter spectrum that describes all of the possibilities of objects as matter waves.

Our universe is both a pulse of matter in time as well as a spectrum of the possibilities of matter waves, which is the Fourier transform of the universe matter pulse. However, our universe is not actually made up of the empty void of nothing that we call space. Rather that empty void of nothing that we call space is just a projection of the actions of objects in time and it is matter action that actually separates objects.

Each of time and matter are complex amplitudes with a common phase, but matter and time are also related to each other by the Schrödinger equation. This relationship imposes a quantum phase differential between matter and time, π/2, that is the basis for orthogonality between matter and time as well as the basis of the right angle of Euclidean geometry that matter time projects as space. The conjugate coordinates {m, t} along with the action of the Schrödinger equation provide the basic dimensions of reality that then project a Cartesian displacement that is the right angle of Euclidean geometry.

In the early universe, forces were vanishingly small and matter was an equilibrium of bosons and fermions since there was not yet enough force to condense or freeze bosons into fermions. As the universe pulse collapsed, forces increased and when matter’s rate of change, force, reached a threshold of m_p/m_e, the ratio of proton and electron masses, a fraction of matter froze out from the boson sea as the light elements of hydrogen, deuterium, helium, and other isotopes. Each boson condensate formed into fermions as pairs of atoms with complementary angular momentum.

The same charge force that bound rotating electrons and protons also bound their rotating neutral atoms to themselves with gravity, but in the folded universe, gravity forces were very much smaller than charge forces. The very much weaker gravity force condensed rotating hydrogen atoms into rotating planets and stars that fused hydrogen into heavier elements up to iron. Photon and neutrino radiation not only provides the light and warmth of the heavens, but that radiation also results in star matter decay over and above the decay of space. The coupling of star decay with spatial decay then provides an extra force that transfers angular momentum from inner to outer stars in a galaxy.

Rotating stars cluster into rotating elliptical and spiral disks called galaxies, which are fueled both by the fire of the stars as well as by the angular momentum of the atom. Ever more massive accumulations of matter yield the heavier elements as well as neutron stars, magnetars, and finally, massive rotating boson stars known as supermassive black holes. Boson stars represent the ultimate destiny of all matter in the shrinking universe with an ultimate dephasing of all matter.