Session 9 to Course 14 about Group Action, Part One

Protons are bosons.  Neutrons are bosons.  Protons and neutrons are nucleons.  Nucleons are subatomic particles that exist in the center of atoms.  Bosons are sub-atomic particles with a whole spin. Bosons are comprised, in part, of closed strings.  Closed strings are bosonic superstrings.  Bosonic superstrings are generally two-dimensional superstrings.  Two-Dimensional superstrings are basically hoop shaped, in general.  In the history of the universe, there are many times as many closed superstrings than open superstrings.  A superstring is considered open when it is not a closed-loop-based topology of interconnected first-ordered point particles.  There are subatomic particles that come together to form electrons.  And, there are subatomic particles that come together to form nucleons.  Once an electron is formed, all of the strings that work to put together the plain kinetic energy of this said general format of particle are open one-dimensional superstringsof discrete energy permittivity.  Likewise, once an electron is formed, all of the strings that work to put together the mass of this said general format of particle are closed two-dimensional superstrings of discrete energy permittivity.  In the Gliossi-based field of any superstrings -- in-between any given arbitrary superstring and its directly corresponding Fadeev-Popov-Trace -- there are gauge-bosons that work to "pluck" the individual second-ordered light-cone-gauge eigenstates so that Schwinger-Indices may form.  Gauge-Bosons are closed strings that act as heterotic superstrings.  Heterotic superstrings are closed superstrings that do not act as two-dimensional strings of discrete energy permittivity.  Once a nucleon is formed, all of the strings that make up the mass of the said nucleon are closed two-dimensional strings of discrete energy permittivity.  Likewise, the superstrings of discrete energy permittivity that work to comprise the plain kinetic energy of nucleons are open one-dimensional superstrings.  Nucleons vibrate, yet, these are relatively pretty steady-state in general -- when in terms of their transversel energy, unless these are acted upon by an outside force.  Nucleons tend to have a relatively small amount of kinetic energy that is not in static equilibrium when this is compared to the kinetic energy that works to form electrons -- as may be extrapolated by the condition that, in an atom, the nucleus is a vibrating steady-state phenomenon in general, while, the electrons that surround the nucleus are constantly moving in both a transversel, radial, and in a spin-orbital manner as these cycle around the mentioned nucleus.  Yet, as a particle that is comprised of atoms accellerates, not only do the electrons gain mass,yet, the nucleons gain mass due to the directly associated Lorentz-Four-Contraction in a proportional manner.  This increase in the mass of the said nucleus increases the number of two-dimensionl strings that the said nucleus has -- when in terms of its mass.  I will continue with part two later!  Sam.