Quantum Magnetodynamics by Relative Quantum Mechanics
Magnetic Field Simulation by CRQT Function Network 3D Modeling at Picoyoctoscale (10-36 m)
by ( Quark+Gluon+String ) Compound Topologies
The GT integral atomic modeling function builds pymscale virtual magnetic fields with a complete set of animated
3D force fieldons. Now, the molecule or circuit's magnetodynamics may be graphically presented for interactive analysis or
design work of intensive modifications with accurate, onscreen visual and numeric data by selection of volumes and events. The
MAVCAM graphics' kinetics are driven by the relative quantum physics functions of the virtual particles imaged, achieving exact
emulation of how magnetic fields interact with heat, _/+ charge, or other parameters, based on their data sets' combinations
within the operative CRQT function network. One way to look at the reductive 3D mathematical MAVCAM system for quantum
magnetodynamics is to map the basic process of atomic internal magnetic energy oscillation from the beginning point of
exemplifies quantized magnetic force, idealized as a durable metalloplastic rod about 36 picoyoctometers long with three
faces.
String Models as Quarks that are Magnetic Force Particles of the CRQT Virtual Atom
Definition of force field quantum units has advanced from abstractions to a specific spectrum of seven to ten quarks. At right, the structure of a subatomic particle illustrates how initial quarks, renamed varietons, are bonded end-on to
transfer force through a waveparticle's body. A quark lattice can be a {gluon+quark} glork crystal with massive qualities that sustains it's topology by a dynamic pulsation cycle of quantized internal changes. Each of the
varietons {k (1-10)} delivers a unique 'color' of flowing symmetry and variety to it's binding lattice, which is essential
to the smooth distribution of mass and energy throughout an atom's EQT energy cloud. Those 10 designs direct
force into different types of flowpaths, making relativistic particle physics a science of quantum system analysis,
with quark lattice energonics as the set of mechanisms which may be illustrated by a spectrum of color coded
energy and force field particles. That dovetails with the succinct CRQT function network, a definitive codification of
quark color group theory for Planck scale thermodynamics in which each equation is a dense video synthesis of
convergent tasks. This gives swift, comprehensive, 3D, animated, interactive results.
The number of different varieton compound designs is myriad, and magnetic energy particles operate by relative quantum mechanical functions which
synchronize, mediate, or amplify within the psi's internal magneplastic circuitry to balance the symmetry of space and heat. That unified magnetodynamic
atomic energonomy may be known in detail by quantum particle physics research with RQT analysis to build informative flowcharts and topological maps
for design of new magnetic field applications or refinements for transistorized IC microchip, molecular, or material magnetic field architectures. It could even be said to be quagnetic.
Quarks are Varietons that Give Variety of Topology to the Energy Particles
Magnetic fields condense progressively as varietons diffuse radially from the nucleus. Those compound quarks are the hadrons, such as the hexon shown at right, which has four symmetry groups and four component intricons.
Hadrons of rising mass develop as a psi's magneplastic force matrix builds density, leading to more complex
diskons that exist in aligned arrays loosely joining masses, on many scales of extent. The quantized gain of
magnetic field stabilizes and advances by accelerations of magneparticle size.
A hexon may precess by further condensation under quantum symmetry
group (*1) force to form a tetrix, at left, of ~50 pyms of size. This diskon's
precession to greater mass develops by the process of intrication, building
particles that act as a supply of varietons to magnetic fields that undergo stress
due to events of atomic photon gain. These diskons are termed matrixons,
and their symbol includes the counts for the number of faces and number of intricons, giving the hexon the symbol: m6x4n. An interactive, animated model for the magnetic field of a current
carrying wire will show the proliferation of specific matrixons, depending on the level and rate of excitation, and their
spin-emission of force. Learn more about quantum magnetodynamics in picoyoctoscale 3D animation in the
At right, a view of consecutive force field bonding stages illustrates the results, the accumulation of coral fan type topology with quantum symmetry
group progression. Note how each stage of matrixon structural gain adds six
more open faces for particle absorption-emission interaction, an example of how
quantum rules seem to defy plain, continuous function analysis. While the
precession to eicoson adds six intricons, with gain of 6 faces; the next quantum
jump to m18x22n adds twelve, with gain of six faces. The progress of symmetry
groups throughout force field intensification processes creates a synchronized
relative quantum mechanism of unified symmetry that distributes force and
energy smoothly. That unique characteristic of symmetronic force gain leads to
important quantum rules for thermal interaction with magnetic or electric charge
fields, defining the possible modes of synchronous atomic states in terms of
supersymmetry driven by superworkons. That is one example of how MAVCAM study of molecular biology or transistorized integrated circuit microchip architecture allows designs for unified force and energy relationships of greater
accuracy and power than before.
Diversified Matrixons and 3D Magnetic Particles Combine Field Effects
to Unify an Atom's Electron Cloud Energy Structure
The atom may be looked at as a system of particles operating in response to it's environment by
a function network flowchart of restoration of momentum. Left, an idealized, combined pymscale scene drawn from the CRQT topofuncs displays magnetic field vortex downput to the nucleus with emissions of a spectrum
of magnemedons with some matrixons. The basic magnetic energy particles generated by MAVCAM define
subatomic magnetic fields with quantum mechanisms for psi's emissions of electromagnetic waves with
frequencies through the ultraviolet and X-ray photon sizes. Greater photons engage superworkon stages of
atomic excitation, as well as the supersymmetry and ultrasymmetry fields symbolized at top-center by
" U*Sn ". Those operations develop a particle image for the magnetic flux variable B, a hadron of variable
frequency. At lower left a graviton spins in interaction with the atomic force fields.
These particles are defined exactly, and coincide with the joule energy identities of the nuclear magneton
and beta magneton, allowing clear interpretation of quantum physics mathematical event models by video
images, animated by relativistic transform functions. That means unprecedented certainty for safety and
economic efficiency in science or engineering office design or analysis tasks, an ideal infotool for modeling
the magnetic field around a wire; an advancement of ~27 powers of ten in scale for electromagnetic simulation
| Nuclear Input/Output of |
| Magnetic Force/Energy |
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