Grand Unified Theory | Quantum Physics Equations for Atomic Modeling

Grand Unified Theory of Matter and Energy MSW 2007(R) (32 bit browser) Web Pages 5 Quantum Topics

Grand Unified Relative Quantum Subatomic Energy and Force Topological Wavefunction Physics MSW 2007(R) (32 bit browser) Web Pages

I. Introduction to The Crystalon Door, presenting the

grand unified theory, with a full display of the new

relative quantum topological (RQT) atomic model

Select the link above for all 5 topics. function.

A full display of grand unified II. Symmegraphics Gallery of subatomic waveparticle

feature stories, graphics, product topologies, RQ physics topics.

discussions, and commercial infotools.

III. 'Clough Essays in Quantum Mechanics', introduction,

with the essay title 'The CRQAM Solution to the

Schrodinger Equation'.

IV. Displays of the Softicon + Silicon Workshop 1-3

nanoscience MAVCAM (Molecular or Material

Animated Video Computer Assisted Modeling)

Scroll down for: software build projects, atomic imaging software

flowcharts, and commercial infotools for picoyoctostructural

1. Atomic Modeling, Particle Modeling MAVCAM circuit or molecular data imaging software

2. Electron Imaging build projects for enterprise.

3. Photon Quantum Mechanics

4. Quantum Nanoelectronics for Exact

3D EM Full-Wave Solution Modeling V. Graphic particle physics for nanotechnical design.

5. Atomic Imaging, Atomic Structure Learn Planck scale quantum physics basics.

6. Nanoscience, Unified Particle Physics Illustrated Discussions of unified particle physics

7. Schrodinger Wave Equation with clear, new RQT equations for topological solutions

to nanotechnical design or analysis tasks, like 3D EM

full-wave solution IC chip data point modeling.

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Valid Nanotechnical Particle Modeling Physics | ATOMIC THEORY |

The grand unified theory is presented by Symmecon in conformance with the unopposed motion of disclosure in U.S. District (NM)

Court of 04/02/2001 titled The Solution to the Equation of Schrodinger; and U.S. copyright TXu1-266-788, 11/07/2005, The

Crystalon Door.

The Unified Atomic Topological Model Function

These quantum physics equations are ideal for electrical engineering as a wave function

network of subatomic topological definitions, which apply relativity to develop a complete atomic

model, an exact physics imaging infotool for nanotechnical energy field data mapping. Now quantum

electronics is a reality in terms of physics analysis down to the picoyoctoscale (10^-36 m) with

quantized heat and electromagnetic fields. The new GT integral atomic modeling function is the

achievement of unified quantum mechanics, in equations with their particle images.

The GT function is an exact topofunc of one atom, a video analysis tool for physics, which

draws the 3D interactive animated image using symmetry quantum numbers as a variable.

This infosystem is designed to fit the chemistry of integrated circuit semiconductors with

clear relative quantum mathematical development of the femtotechnical details needed for

Electron chemical engineering tasks. The new quantum mechanics portrayed in The Crystalon Door

Topology reveals the secrets of quantized probability in circuits, wavefronts, magnetic energy fields, and

.................................................. thermal layers. Symmecon presents a complete system for MAVCAM: Molecular or Material Animated

Interactive Video Computer Assisted Modeling.

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Design Electron Imaging Software Build Programs, Flowcharts by TCD Physics Formatting

When you open The Crystalon Door, a dazzling quantum physics atomic model appears, illustrating the attotechnical and smaller scale

quantum electronics details desired for decisive electrical engineering design or analysis projects. The electron may now be modeled as a

femtoparticle of crystallized forcons, point mapped by the electron wavefunction within or outside the GT integral atomic function. Now the

CRQT function network opens designer electrons to research and design offices. The grand unified theory of matter and energy innovates

safety and precision for chemical engineering as well, introducing a format capable of authentic picoyoctometric atomic modeling accuracy

when used with the Softicon + Silicon Workshop 1-3 software build projects and the list of Symmecon grand unified theory essays and support

products. This format mirrors the Schrodinger wave equation approach, applying series expansion and the boundary value method to give an

exact atomic wave function with a solvable correlation function for mapping the set of virtual photons onto the timespace manifold of the

electron cloud region.

Photon Quantum Mechanics by Energy Imaging Topofuncs

Photon quantum mechanics is clarified here and physics 3D modeling tasks for chemistry or

electrical engineering tasks reduced to straight mathematical calculation by topological wavefunctions

that quantize heat in perfect agreement with the imaged fundamental physical constants; h, h-bar, SB delta,

nuclear magneton, beta magneton, and Boltzmann constant k (series). Now the atom's electron shells

and orbitals are visible in agreement with their ionization energies, as plotted by the new GT integral quantum

physics equation. Molecular processes gain full 3D graphic data mapping for advanced picoyoctoscale

research, design, or analysis tasks in bioscience or chemical engineering. ULSIC models can apply these 3D

EM photon energy and force field data images for qubit, single photon, and plasmon design and analysis project

high resolution studies.

The grand unified theory of physics is perfect for students, scientists, software developers, and

advanced readers. It will give years of study for advanced quantum mechanics model builders applying quantum physics theory to

nanotechnical scenes requiring detailed electromagnetic energy field imaging, on the picoyoctometric scale.

* Grand Unified Relative Quantum Nanoelectronics *

Picotechnical Semiconductor Integrated Circuit Modeling by Energy Field and Electron Modeling

through New Physics Function Network Calculations

The grand unified theory is a stepwise guide to the tasks of quantum electronics modeling for chemistry, chemical engineering,

electrical engineering, and any nanostructural analysis work. TCD is a science thriller providing the grand unified theory of physics as a

vivid display of the relativity of the quantum atomic model, a video analysis infotool for ultramicro scale analysis. A CRQT MAVCAM

Softicon office will be capable of very large scale analysis and design tasks for femtostructure and heat field topology, atom and electron

pulsation, and atomic imagery, with electron flow models for applications such as ULSIC design or analysis. Now microchip architecture has

a grand unified atomic model for every design project feature with exact, smooth fit to Schrodinger wavefunction particle probability mapping.

Transistorized silicon wafer picostructure may be studied by interactive atomic nanoscale and femtostructural mathematical imaging for

electron microscope focus enhancements. Photon topological analysis for quantum bits with noncollapsing wavefunctions using MAVCAM

will boldly display the force and energy field topologies of emergent photon interface interactions, while giving photon control estimates by

a variety of advanced quantum physics equations.

Semiconductor femtostructural details with attoscale thermal wavefunction resolution capable of discrete thermal particle

topological imaging and thermal energy or force flow modeling is now a reality in Symmecon data processing systems. Electromagnetic

photon emergence may be imaged in picoyoctoscale detail by animated, interactive mathematical modeling calculations of exact relative

quantum predictability. CRQT MAVCAM images electromagnetic wave picoyoctostructures in terms of single photons, including all; spin factors,

thermic tints, magnetic lattice symmetry states, polarizations, (-) electric charge picoyoctoscale topological distributions, and space

permittivity features in pymtechnical differential modeling quantum equations with quantized supersymmetry and GT relativity. Photon

topological pulsations, internal structural mechanics, and environmental interactions are modeled exactly for all particles, fields, and

waves using plain, clear relative quantum particle physics equations. This new wave imaging process is ideal for 3D EM full-wave solution IC

circuit modeling software.

Electron flowpaths receive special attention by the design of MAVCAM, which has an ideal focus for the femtostructural topics of

electron topology. Analysis of the individual electrons in a semiconductor IC chip model can be directed to specify any series of changes

which they undergo while flowing through the virtual circuit conductors, or interacting in the transistor components. The mathematical

achievements attained for those types of processes enable a researcher to define the set of electrons in the sample volume for their

individual picoyoctotechnical topologies, and the video (with cutaway) model of each of their changes of state as they endure stresses applied

by the work demands of applied bias and material chemistry.

This is presently intended to give the MAVCAM user a capability for selecting any lower microvolume of current flow in order to view

the electrons there as 3D mathematical model images, a task that will call for a good deal of data processing power. Those keyboard-

interactive electron model images are named wavectrons, in line with the video relagraphic (relativistic waveparticle force data point

graphic) maps of electron precessions as they advance to accelerated states. The computer simulation will record and process each selected

wavectron's internal state and display any of those images' cutaway, surface, or outer charge cloud details.

The negative charge cloud around a wavectron's core consists of particles ranging from about [ 60/125 h ] upward, and those point

charges are well enough defined to give an array of new circuit component design concepts, including new chip control features for

optimizing the pymtechnical qualities of wavectron performance. These techniques will produce electron images which display subtle

differences of topological change as varying color tints, with exact pymjoule force and energy particle data readout tables for selected

wavectron regions.

The Crystalon Door solves the Schrodinger wave equation, giving an equation-by-equation series of mathematical steps, separated

into nine chapters with 310 pages and 375 charts, tables, diagrams, or illustrations to give a full discussion to each stage of the atomic

states during equilibrium, absorption, and output stages. These imaging function guides discuss cycles in terms of zyctoseconds and their

separation into individual chronon events. All five chapters for specific waveparticles explain those topologies in atomic physics equations

that are clear RQT functions, displaying the development process for their 3D data images along with each of their basic stages of quantum

advancement to excited states, pulsation cycles, and for all of their force fields in terms of picoyoctometric forcon particles.

The Crystalon Door

Table of Contents

1. The Model of the Atom 4. The Electron Waveparticle 7. Thermons as the Fundamental

2. Transformation 5. The Magneton as a Particle with Mass Particle of Heat

3. The Spectrum of Particles 6. d³S₀Energy as Positrons 8. Compound Electromagnetic

Waves

9. Clough Theory

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Atomic Imaging Builds

for Chip Design Software

Picoyocto Technical (10^-36 m)

3D Video

Interactive Animated

Display

Modeling of

Subatomic Energy for

MAVCAM infotools for

PHYSICAL CHEMISTRY, SUBATOMIC PARTICLE PHYSICS,

TOPOLOGICAL FUNCTIONS, AND ENERGY FIELD REACTIONS.

Including Softicon 1-5 MAVCAM pymscale imaging build SDK.

Nucleons > Electrons > Rays > Fields > EM Photons, Waves

{Including Electron Shell Energy Density, Saturation States, Thresholds,

and Events}

Pymscale Atomic Structure Models for Molecules or Materials

Atomic structure is known by waveparticle physics equations and chemical analytics to have a list of dimensions and qualities. Standard models give each element a weight, size, nucleon count, electron shell topology with orbital levels of (+) charge ionization energy potential, and heat capacity.

There are measured parameters for a pure element's material qualities; heat

conductance, magnetic susceptibility, electrical conductivity and resistance, capacitance, malleability, tensile strength, ductility, hardness, density, melting point, nucleon spin, nuclear magnetic resonance, wave absorption and emission frequency spectra, vapor pressure, and others. All of these details give atomic and material microtopology well based definitions of spheres with electrical charge field sizes and electron valences, but those known factors do not go beyond that to put forward a model of regular picometric, and electron topological femtometric, detail. MAVCAM is picoyoctometric, modeling hs as ~175 x 10 ^{- 36}m, ~175 pyms in diameter.

This concept of RQT wavefunction analysis focuses the calculation of atomic structure by mathematical synthesis of the individual elemental atom, named psi (Z)'s data point map, achieved by plain combination of the proven relative quantum waveparticle physics functions to make a compounded psi topofunc of more than 60 specific variables. That builds a complete wavefunction with quantized space, heat, and symmetry, a nucleus pulsating in mass at the frequency [ Nhu = e/h ], by radiation of picoyocto technical (pymtechnical) force field particles that carry exact, valid energy values ranging from

[ (1/125) h] |---> [(10/125) h ].

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Now a plain central image evolves by point set symmetry mapping as the series expansion of psi's nuclear radiation of the four force fields maps the necessary stages of forcon output, a quantum physics equation network.

1. Chronons Time Field

2. Probablons Probability Field

3. Varietons Magnetic Field

4. Gravity Gravity Field

While those 4 types of particles commute to and from the nucleus at the function defined rates, the rules of relativistic quantum mechanics compel a set of specifications for each one's exact energy equivalence in joules. That is true due to the limits imposed by the time, space, mass, and energy equations now implicit in the RQT psifunc. The workon h value's effects on the rates of nucleoplastic transformation quantize the possible sizes of the forcons emitted. That allows formation of only the spectrum of force fieldons now labeled the relatons, for relativistic intertransformative force fieldon particles. Those are sometimes named strings, or superstrings, the components of hadrons

Hence we may define the law of atomic quantum force topology as follows. When the atom's Schrodinger wavefunction is solved for the series expansion of nuclear radiation rates used in the RQT GT [ Gravity <--> Time ] integral atomic topofunc the spectrum of force relatons emitted may have only that one set of exact relative quantum ruled joule values. Next, however, since symmetry is quantized the forcons will each also hold only one possible topology.

This first level of correctly quantized atomic relativistic mass flow gains pymtechnical video definition due to the strict, mathematically demanding conditions imposed by the RQT function network, all of which fit together smoothly to build the psifunc's outer heat capacity energy cloud topology in authentic sizes and physical distributions by continuation of the calculation process under operations that also fulfill the atom's equation for total internal momentum. Now every subatomic psi particle with mass, force, or energy is clearly defined in atomic equations, and that symmetry of design may be solved for any set of environmental temperature, pressure, and field effects.

Force fields emanate from the nuclear surface layer of nucleoplasm, as illustrated above. The plasma appears, by point set symmetry mapping of relaton topology, as a dense, viscous fluid composed of sinusoidal chronons, globular probablons, linear varietons, and conic-vortical gravitons. These now hold video images with data definitions capable of fitting into one continuous, pymtechnical, topological process of atomic relative quantum pulsation with regular, periodic cycles of emission and absorption of force. The atom's motion will now have relativistic gain and loss of mass as topologized particles while it's velocity changes, an achievement of RQT physics function networking that is quantized for symmetry, gravity, time, probability, space, and a full, discrete spectrum of waveparticles transferring momentum along any possible circuit within an atom's internal volume. The quantum atomic model will gain and lose specific photons of electromagnetic wave energy, as a pymtechnical video display portrays, in agreement with measurements and the Stefan-Boltzmann thermal photon output rule.

For more details of chip design software and atomic imaging software development, with flowcharts and commercial infotools for planning and operation of Symmecon CRQT analytical systems, select the link below and then choose Commercial Infotools.

|-----> | Atomic Imaging MAVCAM Infotools |

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Mathematical Modeling

Analysis of Chemicals

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Nanoscience in Terms of || How and Why

the Unified Particle Physics || Work is Energy

of Atomic Structure || in h Units

An Introduction to Grand Unified Topological Science

as a New and Digital Analysis and Design System

of Calculation and Reasoning

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While searching literature for clear views of many science topics a reader finds that

mathematical models for chemical, electrical, or mechanical scenes are made up by classical physics formulas. That method approximates how bulk materials or samples respond to stresses in terms of energy, force, work, momentum, pressure, and heat. New physics has brought greater dimension to chemical analysis, such as for infrared absorption spectroscopy, by integration of MAVCAM techniques into the interpretation of analytical data. In short, when a typical Infrared spectrogram for an organic molecule is evaluated the absorption peaks have tantalizing correlation with the CRQT energy particle sets. We may soon be able to model these IR uptake events in terms of their individual pymscale energy intermedon orbital and shell filling sequences. Those innovations deserve study in terms of the completion of the analytical model through picoyoctoscales, and the widening vista of new chemical analytical instruments and processes that they portend. That all depends on understanding of the RQT function network's power to video image any atomic scale volume, and model the reactions which those atoms or molecules may have. The basics of that system have wide implications unveiling an infinitude of ultimate force and energy field details.

When electrical or magnetic fields are discussed, the prequantum format breaks down due to the more precise results found through the functions for frequency [ e = h(Nhu) ] and wavelength [ Lamda = h / mv ]. Those factors always have units of h, the workon energy or work value. CRQT MAVCAM defines workon topology and mechanics. Similarly, subatomic particle momentum is found to be quantized, and more quantized, or simply quantum, factors are found where equations use the values for h, delta, nuclear magneton, or the beta magneton. A new quantum physics theory has resolved the subatomic energy particles in 3D videographics.

Since the examination of individual molecular structures in chemistry, or comparable small numbers of electrons in electronics, must be performed by quantum physics calculations using those fundamental physical constants, the video models for those lower microscopic regions of femtometric dimensions of atomic structure must be built with intrinsic quantum functionality.

The electron model will demand femtometric model definition. Those features spell the inexorable dichotomy between classical and quantum physics, and where the particles are unimpeded masses subject to regular environmental forces their translational, vibrational, or rotational motions must also have relativistic functions for definition of their equilibrium states or reactions.

So now the stage is set for molecular wave interactions, reactions, bond definitions, phase changes, and semiconductor or electronic circuit processes to have a whole new science in terms of quantum relative physics equations which explain the nanostructural, and femtostructural details needed to advance the art.

CRQT physics was built with those unified particle physics concepts in mind, and moved into the field of quantized variables for the four primary forces, as well as space and symmetry, in order to synthesize pymtechnical video models for safe, efficient science, engineering, and technological work. This system builds the exact atomic topofunc with all variables, and defines all extratomic particles, fields, and waves in the same RQT (Relative Quantum Topological) function network. Now the new science landscape looks like a dynamic spaceon (spatial ocean particle) of unified, well defined particle interactions on various quantum levels of force exchange. All known energy and matter is calculable by CRQT physics, with pymscale certainty, in the unified theory of physics.

Here are a series of topics for advanced science lovers featured in the navigation bar tag for Atomic Model Views. Each has some discussion with many new diagrams, illustrations, examples, and key calculation guides to help learn all of the details of 3D atomic structure and wave RQT modeling for the interactive analysis of design, research, or study project subjects.

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***** Energy Particle Structural Equations

***** Ultrascience Synergistic gains of data processing power lead toward modernization by new and ultrascience, results of the leverage applied by CRQT infotools.

***** Schrodinger Wave Equation

***** Electromagnetic Wave Photon Topology and Dynamics

***** Chronons, Probablons, and Magnetic Fields

***** Atomic Structure

| TOP |

. Unified Particle Physics

Relatons may unite by field

bonding effect, building larger waveparticles that are compounds of force particles.

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The magnetic field is a matrix

of dense, spinning particles that distribute mass of several types.

The hexon is a magnesic, substrate particle of the magnetic energon spectrum.

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A widening series of coral fan

topologies emerge as the atom's nucleoplastic transformation rate gains. The eicosons and their more advanced diskons concentrate energy which will crystallize to h particles of formal magnetic field when the environment's applied stress produces those quantum jumps of psi topology such as electron spin reversal. Atomic energy fields have strain by evolution of more highly compounded, more intricate force and energy particles, which inexorably develop the mechanisms of electromagnetic wave absorption and consequent output.

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Output Photon Design

The tetrasuper probitalon above is a magnesithermic compound waveparticle which is formed by the action of superworkons during quick atomic events that drive energy both outward, and into more complex topologies with greater ranges of force effects.

That leads to advanced states capable of more symmetric distribution of strain and mass while leading momentum along the Stefan-Boltzmann circuit of photon emission to the environment. That series of S.-B. events has clear MAVCAM video imaging for the three exponential stages of temperature particle acceleration, which may allow specialized conditioning or output photon designs.

Relaton topologies and qualities define subatomic waveparticle reaction mechanics which clearly define relativistic time, mass, and energy transformations in quantized formats.

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Almost any shapes may arise from force field bonding, but the significant are those designed by the quantum symmetry numbers of their crystallization events. That process gives the exact h topology and size within the symmetopol integral series, a proof of the grand unified CRQT theory of matter and energy.

Since the equation displays the relativistic mechanics of time and mass in terms of atomic field topologies the video model is valid.

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Positron Topology

The RQ physics equations of CRQT develop positron particle images in picoyoctotechnical detail as well. The positron equations reveal how electron structural femtotechnical details respond to thermal field force and electric charges.

Positron physics calculations now display electron-positron interactions by RQT modeling.

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Study

Video Modeling of

Positron Particles

of Exact Size and

Picoyoctotechnical

Topology

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Nanotechnical

Materials Analysis

Software Builds for