^^^^^^^^^^^^^^^^^^^^
Schrodinger Wave Equation Particle Physics Calculations
Visit Symsite's mathematical model by selection of the link above for closeup previews of: grand unified
particle physics, plain math based ultrascience, RQT wavefunction mathematics, symmetopol equation operations, grand unified theory physics, quantum physics equations. This page is for math based study of atomic topology and pulsation based on Lorenz- Einstein transform cyclic integral dynamic topofunc animation of pymtechnical
waveparticle topologies and interactions. The grand unified theory presents graphics equations for particle physics and nanoelectronics that give plain mathematical atomic model instructions for nanoscience design or analysis work.
Recent advancements in subatomic particle physics
are pointing along lines that converge at the CRQT function
network for solving Schrodinger wavefunction problems of
atomic topology. The chart at left displays how new science
integrates the electron shells, subshells, and orbitals into
mathematical functions for atomic, molecular, and material
quantum chemistry calculations. Next, the latest particle
physics research may be applied by inclusion of data and arguments to constrain the computation of results. Modern
research correlations include:
1. Peer-reviewed GT relativity verification data on
| New Science Gives the Function-based | [ gravity <> time ] interactions, confirmation of the
| Electron Set Structure for Quantum Chemistry | GT integral atomic function's predictions based
|_____________________________________________| Einsteinian physics with Lorenz time-mass
transforms linked end-to-end.
2. Continuing progress developing the model of matter and energy as composites built of quantum cords or
linear particles. This fundamental concept of CRQT New Physics is the foundation of MAVCAM atomic imaging,
as seen in the unique 3D graphic maps of the 5 energy particle classes generated by the GT integral psi function's
QFT correlation function. Learn these new quantum physics energy equation calculations for molecular topology
by the complete atomic modeling guide The Crystalon Door , as unopposed in U.S. District (NM) Court on
3. Black holes, cosmic energy, and galactic quantum radiation studies are defining the relativistic basic
relationships of matter with space. Advance your models for terrestrial or cosmic research by application of Lorenz
invariant matter and energy particle functions with intrinsic spacon variables. Learn how the Clough space
transform solves mathematics problems for temperatures and pressures with exact 5/2 kT results. The isobaric
kT factor has 3D CRQT video energy field topological display with picoyoctoscale resolution and interactive
animation when imaged by Softicon + Silicon Workshop 1-3 software development kits.
4. Supersymmetry particle physics and 7-10 dimensional universe quantum 
mechanics are basics of the CRQT GT atomic function network. Learn how the h
holds tetrasuper synchrolink topology which aligns electron spin states. Quantum
symmetry is central to CRQT physics, with each symmetry field particle having about
10 -- 56 J. These recent researches in quantum field theory are building the
framework of the grand unified theory equations as subatomic particle research
converges with cosmic science. CRQT has the data for 7 dimensional universe
supersymmetry based on the primal 4 dimensional U4 quantum of ~10 --44 J, the Q4.
________________________[ O ]-----------------------| <> |________// - c \\_______|
New Physics, Grand Unified Theory Physics
The focus of grand unified theory physics definitions and calculations in Atomic Model Views is for
hard science students, professionals, and advanced readers interested in studying the unified theory of physics
by quantum physics equations. Quantum physics theory is indexed in CRQT science to include quantum physics
relativity in one function network of clear algebra and calculus equations which build an exact atomic model of
data points by combining the well-known Schrodinger wave equation energy physics equations to synthesize the
intersection of their point sets. That means there is a complete set of variables, including those for quantized
force, quantized negative and positive charge, quantized magnetic field, quantized heat, quantized time, quantized
probability, quantized symmetry, quantized gravity, and quantized space.
Quantum mechanics equation construction is explained in The Crystalon Door as a fun and easy
way to analyze any physical science example in terms of atomic responses to photon gain by force
and energy field topological changes. That is the CRQT atomic wavefunction named the GT integral
psifunc, a quantum physics equation derived from the physics unified theory. CRQT function networking
is the application of the new energy physics equation set to a sample volume by inclusion of all known
variables, and operation of the thermal cycle expansion routine to draw the models. Quantum energy
equations are picoyoctometric point mapping functions when they are integrated with quantized force and
energy, capable of displaying the topological pulsation dynamics, and kinetics of computerized
waveparticle models accurately.
Quantum theory equations may be completed with quantized spacon sets for nanometric examples
by application of MAVCAM techniques found in TCD and the Softicon + Silicon Workshop 1-3 video software
build projects. Scientists and engineers may wish to see a more mathematical, and wide-ranging general
discussion of how CRQT MAVCAM operates, so Atomic Model Views begins the hitech presentation
by a series of introductory feature stories using step-by-step definitions for atomic topology with the CRQT
energy physics equations of the grand unified theory. More detailed and mathematical essays are found in
positron topology in exact 3D graphic equations.
The grand unified theory of physics expands horizons for nanotechnical commercial science as
well as academic pure science, displaying examples of how quantum mechanics equations are now
resolved for the set of energy particles of a psi's internal energy and bond states. The new function
network defines each of the ultramicro particles in the intermedon spectrum of: h, h-bar, delta, nuclear
magneton, beta magneton, k (series), 3/2 k, 5/2 k (series)
Quantum Theory
Schrodinger Equation Solution Topodynamics
Grand unified theory quantum physics is simplified by use of quantized symmetry with installation
of quantum symmetry numbers that designate topologies and each electron position by shell, subshell,
and orbital. That is the solution to the Schrodinger equation for one atom. It changes quantum physics
energy science by giving a direct link from each atomic topofunc's structure to their sequence of aufbau
orbitals, displaying the exact probability densities, but going beyond that to specify the classes and
densities of positrons, workons, superworkons, thermons, electromagnetons, and magnemedons.
TCD illustrates the quantum physics energy changes atoms undergo when their environmental surroundings interact
with them. Quantum electronics will gain new dimensions
when MAVCAM is applied to design or analysis tasks for
modeling integrated circuit electron topology, reactions, and
kinetics.
________________________________
Beginning Grand Unified Relative Quantum Topological Atomic Modeling Analysis
Work with the nanostructural details of semiconductor IC chips is optimized by application of mathematical models for the masses
and energy fields of the atoms, and electron topology of the example. Thinking of exact electron flow in nanoscale circuits focuses on
that material's structural arrangement as the semirigid framework which should be optimized to concentrate the electronic, and specifically
digital work intended. Advanced quantum computer component designs based on single electrons or smaller attoscale energy objects may
be constructed in MAVCAM with picoyoctometric detail for exact interactive video experimentation. Qubit science progress relies on data
density with exact topological definition of +/- electric charge waveparticle fields, workons, superworkons, thermic body fields,
electromagneton field-arrays, and magnemedon waveparticle field-matrix. The same is true for chemical reactions or other material
operations of nanometric dimensions. Hence, the best procedure for a design or analysis project is to build the interactive video model of
the sample in it's environment by writing the set of math equations which will define the model volume as a data point map with all of the
variables materially present, in their true algebraic, differential, integral, related operative system.
.............................
When that topological model is constructed it is next animated by inclusion of the force and energy fields which control the
interactions of the elemental atoms involved. The CRQT function network does that, with different features that simplify and direct the
work process to guide the study of the bevy of possible events on the nanotechnical scale.
................................................................................
The diverse research activities using studies of the structural and energetic interactions of atoms will need to reduce the scale of
those models to define all of the problem's relevant factors with exactitude. Now the S system of GT integrals solves those difficulties
and introduces the next generation of science research and development by defining force and energy field topologies and their relative
quantum interaction mechanisms. A single electron's animated video model may be enlarged to study it's cutaway views in picoyoctal
forcon particle detail.
A study of the physics of a molecule or material only one to several hundred atoms across may now use MAVCAM to display the
exact reactions of those samples on a video screen with interactive data panels and closeup, cutaway views, analyzing the series of
descending ultra and supermicro scales of volumes to discern any facts needed to make safe, intelligent decisions. Now the CRQT video
system opens the physics of picotechnical structure in clear detail. A scan of the reductions of scale which proceed as a mature MAVCAM
program focuses on subatomic structure will help to guide the discussions of unified nanoscience.
Ultramicroscale Terminology for Size Units
-------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Lower Microscopic I. Nanometers 10 - 9 meters
A. Picometers 10 - 12 m
B. Femtometers 10 - 15 m
Ultramicro Region II. Attometers 10 -18 m
A. Zeytometers 10 - 21 m Zeyts
B. Yoctometers 10 - 24 m Yocts
C. Picofemtometers 10 - 27 m Pifs
.................................. D. Picoattometers 10 - 30 m Picams
Supermicro Region E. Picozeytometers 10 - 33 m Piytoms
Pymtechnical Region F. Picoyoctometers 10 - 36 m Pyms
-------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
This vocabulary, and a few added innovations, will fit the tasks of electronic circuit, or molecular video modeling. Proceed to
the link below or above for new science grand unified theory particle physics previews to start solving problems of chemical, electrical,
and material physics.
Quantum Nanoelectronics Data Image
.............................................................
_
__________________________________________________________________________________________