A New Invention for Atomic Imaging
Modern quantum mechanics focuses the atomic model theory
to display exact picoyoctoscale magnetic field simulation for biomolecules or digital circuit models. That is due to the new combinations of Einstein theory quantum equations with Lorenz transform functions. Learning the physics of atoms is fun and easy with the RQT calculus functions, giving a complete system of physical science based on particle physics.
| Electron Topology |
Basic Quantum Mechanics in Functional Graphics
A plain form of graphical relativistic quantum mechanics for beginners should give the shortest
path for mathematical functional application to construction of atomic models and wave, ray, or field
simulations. That is to say, "What is relativistic quantum mechanics?". Newcomers will find it easiest to
learn the 3D visual functions for the atoms and their subparticles by the stepwise progression of
instructive chapters in The Crystalon Door. The book's layout starts with the basic concepts of
Newtonian, relativistic, and quantum science as definitions for atomic model structure and mechanics,
giving the framework of the series expansion equation method in carefully detailed and illustrated
form. TCD presents only this equation, building one series of topics including new, exact science
definitions for quantized space and time.
That quantitative basis continues through the entire CRQTS function network. The basic atomic structural function outline is followed by the complete explanation of the Einstein-Lorenz relativity functions for energy, time, and mass. That introduction describes how the atom's nuclear radiation of gravity and time force field particles is limited only by time and space constraints, the fundamental GT boundaries of atomic pulsation at the {Nhu=e/h} beat. Next, the atomic nuclear model is clearly calculated by the GT integral function. The method of quantum symmetry number assignments along the series differential was perfected to match atomic topology to electromagnetic interactions. The full spectrum of energy particles building an atom's 5/2 kT J internal heat capacity energy cloud is computed, a set of 26 particle sizes with exact, quantitative, picoyoctometric structural detail for each.
Chapter four illustrates the electron wavefunction design, defining it's pulsation mechanism of negative electric charge particles and magnetic field energons. It, like the energy particles, is a compound of force field particles of four types:
time, probability, magnetic, gravity.
| Magnetic Force and Energy Process |
The final chapter explains the quantized structure of space and the primary quantum of which
the forcons themselves are built, the Q4 of ~10- 44 J. That system of atomic and spatial definitions and
functions allows the reader to set up and calculate any problem of; atomic, molecular, gas, liquid, solid,
wave, ray, or field construction. The result will always portray a neat topological model animated by
pulsating atoms radiating discrete force and energy fields, waves, and rays. The RQT models fit
classical Newtonian ones closely, solving Schrodinger wave equation problems, but yield the secrets of
nanoscience by imaging the force and energy which drive electromagnetic or chemical processes by
their relativistic transform functions. Now a student can easily understand and calculate why and how
the electron orbitals {s,p,d,f} have their specific sizes.
Chemical engineers will find TCD the perfect, readable reference 
for design or analytical work. Now the virtual atom build projects are available
for molecular simulations, valid at all temperatures or pressures. Electrical
engineering tasks will advance to a new level of safety and efficiency by
accurate microchip design software builds with exact, picoyoctoscale 3D EM
full-wave onscreen modeling capability.
TCD defines the electron's topology and relative quantum physics in
stepwise detail. One of many examples is the h-bar image projected by the
GT atomic function, a lattice of Planck scale varietons that are forcons. This diskon is ~175 picoyoctometers in diameter, and has three basic isomers.
Quantum physics analyses in these terms of subatomic particles lend validity
and innovative dynamism to any science or engineering project or routine
office task, such as the magnetic field around a wire or transistor. 
Quantum Chemistry with Supersymmetry
Projects for imaging molecules by this wavefunction system of interactive 3D virtual atoms
now have a clear physics basis for computerization. That is due to convergence of supersymmetry
concepts with the Planck scale fundamental particle model of string-quark topologies. While some
network resulted in bold displays of individual electromagnetic photons composed of ~3-150
picoyoctometer (10 -36 m) forcons. They are Planck scale metalloplastic rods of tensile qualities
named varietons, gluelike probablon spheroids with extensive radial spikes, sinusoidal superelastic
chronons (strings), and tiny yet massive gravitons. Supersymmetry of force is exemplified by the
h-bar, and it's wavefunction will now fit smoothly into quantum chemistry calculations. That is the
advantage of new physics, strict conformity of results to a single system of equations for all scales; and those science office analyses possess unified, relativistic consistency that is due to the quantization
of symmetry and probability.
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| The h-bar Magnetic Energy Particle | The Probablon (Gluon) Force Particle | The Workon, h, Particle of ~150 pyms |
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Supersymmetry defines exact electron orbitals as well, achieved by precise application of
standard physical chemistry techniques for mathematical analysis by Schrodinger wave equation
reasoning. Differential series expansion was used to incude the full subatomic particle spectrum in a
system of { Force <-> Energy<->Motion } relationships defined by {Time <-> Gravity } boundaries of
relativistic transform dynamics. That concept was focused by the atom's correct internal momentum
function to derive the full set of energy particle topological functions, sometimes referred to as the
eigenfunctions. A process for correlation of the nuclear radiation's cyclic output with the sum of all
electron shell region masses with their velocities was found by system analysis: the right set of
variables was designed to illustrate the consequences of the Einstein-Lorenz transforms within the
workon quantized wave equations for frequencies and wavelengths. Final resolution of the correlation
function for mapping the set of virtual force photons onto the timespace manifold of the outer electron
cloud region was achieved by quantizing probability and symmetry.
(C) 2010, Symmecon Grand Unified Theory Marketing Corp.
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