D. J. Scott
[Last Update: June 6th, 2018]

Contents

Introduction
I. Newtonian Physics
I. Particle Physics
I. Quantum Physics
I. The Standard Model
I.a Quantum Field Theory
II. Particles
II.a. Hadron Particles
II.a-1.) Baryons & Mesons
II.a-2.) Protons & Neutrons
II.a-3.) Proton
II.a-3.) Neutron
II.a. Lepton Particles
II.a-1.) Electron-like vs, Neutrino
II.a-2.) Electronic, Muonic, & Tauonic
II.a-3.) Electron
II.a-3.) Electron Neutrino
II.a-3.) Muon
II.a-3.) Muon Neutrino
II.a-3.) Tau
II.a-3.) Tau Neutrino
III.) Darkmatter & Dark Energy
III.a.) Darkmatter
III.a-1.) Extra-Dimensional Matter
III.a-2.) More Probable Matter
III.a-3.) Darkmatter as Tachyons
III.a-4.) Darkmatter as Antimatter
III.a-5.) Darkmatter as Virtual Particles
III.a-6.) Darkmatter as Decayed Matter

Subdisciplines

[Chemistry]

About


About this Website
About the Author
Services & Rates
Contact Me
Donate!
D. Jon Scott’s WebsiteSciencePhysics

☢ Quantum Physics ☢

Words go here.
Copyright © 2017 by Dustin Jon Scott
[Created: September 14th, 2017]
[Last Update: May 21st, 2018]

Introduction



I. Quantum Physics



I. Particle Physics



I. The Standard Model



I.a. Quantum Field Theory



II. Particles

All matter that we know of is made of three types of particle:

Electron, Up Quark, Down Quark

Electron & Nucleus



II.a. Hadron Particles

Nucleus = Nucleon particles

Nucleus = Hadron particles



II.a-1.) Types of Hadron: Baryon & Meson

Baryon (triquark) = 3 Quarks

Meson = 1 Quark + 1 Antiquark



II.a-1.) Two types of Baryon: Neutron & Proton

Neutron = 1 Up Quark + 2 Down Quarks

Proton = 2 Up Quarks + 1 Down Quark



II.a. Lepton Particles

Three generations: Electronic, Muonic, Tauonic

Electron-like (Charged Leptons) vs. Neutrino (Neutral Leptons)



II.a-1.) Electron-like vs. Neutrino

Electron-like (Charged Leptons) vs. Neutrino (Neutral Leptons)

II.a-1.) Electronic, Muonic, & Tauonic

Blah.



II.a-1.) Electron

Charged Electronic Lepton



II.a-1.) Electron Neutrino

Neutral Electronic Lepton



II.a-1.) Muon

Charged Muonic Lepton



II.a-1.) Muon Neutrino

Neutral Muonic Lepton



II.a-1.) Tau

Charged Tauonic Lepton



II.a-1.) Tau Neutrino

Neutral Tauonic Lepton



II.a. Bosons & Fermions

Blah.



II.a-1.) Bosons

Bosons obey Bose-Einstein statistics

Higgs boson



II.a-1.) Fermions

Fermions obey Fermi-Dirac statistics



III. Darkmatter & Dark Energy

Darkmatter and Dark Energy are poorly understood, though their existence has been scientifically confirmed.



III.a. Darkmatter

Darkmatter is typically imagined to be a form of non-baryonic matter.



III.a-1.) Extra-Dimensional Matter

F



III.a-2.) More Probable Matter

If we take the first law of thermodynamics to imply that the most probable outcome for beginning state of absolute nothingness is to remain as absolute nothingness, then the difficulty in detecting darkmatter at anything less than galactic scales, its weakly interacting nature, and its apparent abundance relative to baryonic matter can all be explained by darkmatter simply existing in a state closer to absolute nothingness and being therefore much more probable than baryonic matter.



III.a-3.) Darkmatter as Tachyons

F



III.a-4.) Darkmatter as Antimatter

A particle with a negative charge traveling backward through time would appear as a particle with a positive charge moving forward in time. (Lawrence Krauss: The Higgs and the Story of Science 30:00-35:00 minutes in)

Main problem: Darkmatter doesn’t interact with baryonic matter, but antimatter interacts with baryonic matter violently.

https://www.youtube.com/watch?v=0Fy6oiIRwJc



III.a-5.) Darkmatter as Virtual Particles

F



III.a-6.) Darkmatter as Decayed Matter

F



III.a-7.) Darkmatter as W.I.M.P.s

F