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The proposed Unified Field Theory (UFT) provides
an all-encompassing theory, where physical models of different physical areas
are no longer decoupled and differently scaled according to their different
levels of granularity, (BrK0) pp. 10-13. It is governed by two types of energy, the today’s mechanical
energy (i.e., kinetic and potential energy) and a newly proposed dynamic
energy, (which is in line with Planck's dynamic type of physical law,
(PlM)), and a corresponding hierarchy of dynamic quanta accompanied by an appropriately defined scheme of quanta numbers.
The conceptual design of the fundamental dynamical Hamiltonian
operator is enabled by the Krein space theory, which is basically the theory of
linear spaces with an indefinite metric. The counterpart of the definite norm induced by the inner product of a Hilbert space in a Krein space framework is given by the concept of an intrinsic
self-adjoint "potential" operator (the fundamental J-inner product, e.g. (BoJ) p. 120 ff). It enables the definition of quantum type specific "dynamic energy" inner products for each considered quanta energy system, (BrK0) pp. 1, 27-29, 36. The commutator of two each of those quanta system specific self-adjoint dynamic potential operators are accompanied by a well known result in form of a "variance inequality" enabling an uncertainty principle, (DaS) Theorem 2.1, (FoG), (NeJ).
The UFT provides a
- 2-component a priori dynamic "Ground State" Model
(GSM)
- 2-component a priori dynamic "Perfect Plasma"
Model (PPM)
- 2-component mechanical "Perfect Electro-Magnetic" Maxwell-Mie Theory (EMT)
- 1-component mechanical "Dirac 2.0 Atomic Nucleus" Theory (ANT)
- 1-component Dynamic Fluid Theory (DFT).
It enables
- a well-posed 3D-NSE system for dynamic fluid particles by the DFT
- an enhanced Schrödinger 2.0 operator by the Riesz transform
- a "Yang-Mills" SU(2)-invariance for Dirac 2.0 (mass) particles by
the ANT
- an integrated Plasma Dynamics Theory (PDT).
The integrated
Krein space based dynamic quanta systems can be approximated by an energetical H(1/2)
Hilbert space framework accompanied by the concepts of a dynamic fluid
particle and a related dynamic potential operator, (BrK0) pp. 10, 11, 17-19, 38. The dynamic potential operator can be interpreted as a
compact disturbance of the linear mechanical Laplacian potential operator. This approximation modelling framework is in line with Plemelj’s extension
of a mass density concept (accompanied with the concept of a single layer
potential) to a mass element concept (accompanied with the concept of a double
layer potential), (PlJ). It enables a reduction of the Neumann problem to a hypersingular integral equation with double layer potential accompanied by a well defined (i.e. equipped with an appropriate Hilbert space domain) Prandtl operator, (LiI).
The energetical mechanical-dynamic approximation Hilbert space H(1/2) of the integrated
Krein space based dynamic quanta systems enables a solution
of the 3D-NSE problem. It also provides a modified Schrödinger 2.0 momentum
operator (enabled by the Riesz operator), which is in line with the intrinsic self-adjoint dynamic potential operator of a Krein space based framework.
Note: There are two a priori 2-component mathematical dynamic quanta systems: the a priori dynamic electrino-positrino based ground state quanta system and the electron-positron based perfect
plasma quanta system, see also (BrK14) p. 26. The most aggregated Krein space based energetical systems built from those a priori systems are three types of explicate 1-component mechanical atomic nucleus quanta systems accompanied by implicate 1-component dynamic quanta systems (ref. Bohm's "wholeness and implicate & explicate orders", (BoD1)). They may be interpreted as conductor, semi-conductor, and non-conductor atomic nucleus types.
Note: The dynamic quanta are characterized by quanta numbers less or equal than one; the mechanical quanta are characterized by quanta numbers greater than one.
Note: The a priori GSM & PPM in
combination with the EMT, ANT and DFT enable an integrated Plasma
Dynamics Theory (PDT) avoiding the concept of a Debye sphere.
Scope
The scope of the Unified Field Theory (UFT) includes the scope of the three (independent, just "linked because they seem to have similar characteristics", (GlJ) p. 433) quantum field theories (strong interactions, weak interactions, and electromagnetics), the scope of both relativity theories, the plasma physics, and the solid state physics.
Conceptual design elements
Note: An
indefinite metric in a Hilbert space is one of the unconventional
features of Heisenberg's "Introduction to the Unified Field Theory of
Elementary Particles", (HeW). The conceptual design of the proposed quanta
scheme follows the "principle of Nature" that any
"action" always requires a potential difference or a
"pressure", i.e., there is no physical action, just because there is
energy or a potential. Technically speaking, all Krein space based particle
types are elements of the same underlying baseline Hilbert space; however, they
are accompanied by different (energetical) indefinite & definite inner products and norms
(functionals) for each considered quanta.
Note: The Hilbert space theory provides the mathematical framework of quantum mechanics. The extended Krein space theory (accompanied by the concepts of an indefinite norm and an intrinsic self adjoint potential operator) provides the mathematical framework of the proposed UFT. While quantum mechanics is governed by the physical concept of mechanical energy, the proposed quanta dynamics is governed by mechanical and (newly) dynamic energy. There are several dynamic quanta systems, which are governed by an appropriately defined deductive quanta numbers scheme. The characteristic of this scheme is an implicate (in the sense of D. Bohm, (BoD1)) "potential difference" between the related (particle,anti-particle)-components per each quanta system.
Note: The real Lorentz group L has three subgroups
(orthochronous, proper, orthochorous). Associated with the restricted
Lorentz group is the group of 2x2 complex matrices of determinant one,
which is denoted by SL(2,C). It is isomophic to the symmetry group
SU(2) and
the unit quaternions S(3). In SMEP the group SU(2) describes
the weak force interaction with 3 bosons W(+), W(-), Z, the characteristic of the
beta-decay process. The Lorentz transformation
in special relativity is a simple type of rotation in hyperbolic space. In (LeS) new real linear quaternions are
introduced to obtain a quaternionic version of the Lorentz group (without the
use of complexified quaternions) and a quaternionic metric tensor is defined, overcoming difficulties concerning the appropriate transformations on the space-time.
Note: The perhaps primary application of quaternions
is the quaternion rotation operator addressing the „translation-rotation“
(linear and angular rotation) „permutation“ requirement. This is a special
quaternion triple-product (unit quaternions and rotating imaginary vector)
competing with the conventional (Euler) matrix rotation operator, (BrK0) p. 47, (KuJ).
Note: The spin of
an elementary particle is its eigen-rotation with exactly two rotation axes,
one parallel and one anti-parallel axis to a magnetic field. This is the complex number scheme, where every „normal“
rotation is contained twice. Consequently, an electron has a charge only half
of the Planck’s quantum of action. For a quaternionic equation representation
of the motion of a particle with an electric charge in a electromagnetic field
manifesting the relativistic covariance of classical electromagnetism we refer
to (GiP). In (ArA) a quaternionic unification of electromagnetism and
hydrodynamics is provided. In
(SaM) a generalized quaternionic quantum wave equation formulation is used to
construct general plane waves enabling corresponding generalized Klein Gordon
and Helmholtz equations.
Note: The complex
Lorentz group L(C) is associated with SU(2)xSU(2). It is essential in
the proof of the PCT theorem, (StR) p. 13. It is also the (hidden)
symmetry group of the
Coulomb problem, (BrK0) p. 58 ff., (BrK14) pp. 14, 28. In contrast to
the real Lorentz group the complex Lorentz group has just two connected (!)
components accompanied by a multiplication law for pairs of 2x2
matrices, (StR) p. 14. It is supposed to govern the conservation of
energy laws of the dynamic quanta systems, (BrK0) p. 31.
Note: The symmetry break down from the complex Lorentz group to the (real) restricted Lorentz group may become a characteristic
of the transformation process from purely dynamic energy governed 2-component quanta systems to
1-component quanta systems accompanied by the concept of mechanical energy and the Minkowski space-time continuum.
GSM & PPM
The a priori 2-component dynamic "Ground State" Model (GSM) and the a priori dynamic "Perfect Plasma" Model (PPM) may be interpreted as an Einstein-Lorentz
ether, (EiA5).
EMT
Quote: „…. light beams must have electric stationary
components in the direction of the wave front normal, and that consequently
there must be stationary electric potential differences between different
points along the beam; and that there must be also a stationary magnetic field
in the beam of light with potential differences. Hence, the light beam must
have a magnetizing effect, and the charge of a magnet should be changed by
light“, (EhF1).
We note that the mechanical energy based 2-component electro-magnetic quanta field of the EMT is in line with the "photopheresis" phenomenon discovered by F. Ehrenhaft, (BrJ), (BrK14) p. 22.
ANT
In
the ANT the term "Dirac 2.0 Atomic Nucleus" is chosen to anticipate
that Dirac's single mechanical energy system is extended to a mechanical
x dynamic energy system concept.
Quote: "Dirac's theory of radiation
is based on a very simple idea; he treats an atom and the radiation
field as a single system whose energy is the sum of three terms: one
representing the energy of the atom, a second representing the
electromagnetic energy of the radiation field, and a small term
representing the coupling energy of the atom and the radiation field", (FeE).
The Dirac 2.0 systems provide a mechanical atomic nucleus concept accompanied by the concept of implicate dynamic quanta (in the sense of D. Bohm, (BoD1)). The potential between this implicate quanta pair defines the dynamic energy of the mechanical atomic nucleus. Those systems neither require the hypothesis
of an electron spin nor the existence of the fine structure constant.
The ANT puts the spot on the "Mach 2.0" principle as proposed in (UnA1) p. 156,
which is essentially the Mach principle + Dirac's two large number
hypotheses in the context of his "new basis for cosmology", (DiP2).
DFT
The Krein space based quanta systems can be aggregated/approximated by the
purely Hilbert (energy) space system H(1/2). It is an extension of
the variational mechanical standard energy Hilbert space H(1). The energy Hilbert space H(1) is the domain of the Friedrichs extension
of the classical Laplacian (potential) operator accompanied by the domain H(2). Its related single layer singular integral operator accompanied by the distributional Dirac function provides the mathematical framework for the Newton/Coulomb potential.
The standard Hilbert space systems H(1) resp.
H(2) also provides the variational resp. the classical framework for
classical and quantum mechanics accompanied by the concept of Fourier
waves. The complementary sub-space of the extended H(1/2) Hilbert space
with respect to the H(1)-norm provides an appropriate Hilbert space
based framework for quantum dynamics accompanied by the concept of
wavelets. The latter ones may be interpreted as "a mathematical
microscope", (BrK0) p. 19, (BrK14) p. 37, (HoM) 1.2.
Physically speaking, the compact embedding of H(1) into H(1/2) addresses "the
problem of matter in the Maxwell equations, by explaining why the field
possesses a granular structure and why the knots of energy remain
intact in spite of the back-and-forth flux of (mechanical!) energy and
momentum", (WeH) p. 171.
PPM & PDT
Plasma is that state
of matter in which the atoms or molecules are found in an ionized state. The number of neutral particles (atomes or molecules) in a gas is
irrelevant for the definition of a plasma. The number of positively and
negatively charged particles per considered volume element may be arbitrarily
small oder arbitrarily large, but both numbers need to be approximately
identical (in order to have no internal macroscopic electrostatic fields. The
interactions of electrons and ions are determined by long-range electrical
forces. Plasma physics is about classical statistical fluid
mechanics and classical fluid dynamics. The underlying related mathematical
models are grouped by different physical application areas resp. chosen
mathematical tools accompanied by correspondingly defined different types of
„plasma matter gases“, (BrK0) p. 60. The a priori PPM enables an integrated Plasma Dynamic Theory (PDT).
 Braun K., The deductive structure of the UFT, creative vacuum and perfect plasma, and related opportunities.pdf |
June, 2025
Braun, K., An unified field theory enabling a deductive structure of physics.pdf |
December 2022
Braun K., UFT related list of papers |
Earlier UFT related papers
