The Evans Equations of Unified Field Theory - Alpha Institute for ...

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42 Figure 2-4 Visualizing Curved Spacetime Flat space with no energy present.Two dimensions are suppressed. Visualization in the mind's eye is necessary to imagine the 3 and 4 dimensional reality of the presence of mass-energy. P a s t X t F u t u r e Figure 2-5 Stress Energy = No mass, no stress energy, T=0. No curvature, R=0. Dense mass, high stress energy, T is large. R is large. A dense mass in in the center of the same space. The geodesics, shortest lines between points, are curved. X t The geodesics are curved; they are the lines a test particle in free fall moves along. From its own viewpoint, a particle will move along a line straight towards the center of mass-energy. Medium mass per volume, T = moderate Moderate curvature, R = medium. The mass density to amount of curvature is not linear. It takes a lot of mass density to start to curve space. As mass builds, it , compresses itself. Pressure then adds to the curvature. This can be taken to the region of a particle density also. Mass causes curvature.
The amount of R, curvature, is non-linear with respect to the mass density, m/V = T. Figure 2-6 is a graph of the amount of compression with respect to mass-energy density. When we hear the term “symmetry breaking” or “symmetry building” we can consider the case where the density increases to the black hole level. At some density there is an abrupt change in the spacetime and it collapses. The same process occurs in symmetry breaking. Mass causes compression of the spacetime volume at the individual particle level and at the large scale level of the neutron star or black hole. Spacetime is compressed by the presence of mass-energy. Pressure also causes curvature. As density increases, the curvature causes its own compression since spacetime has energy. This is self-gravitation. Figure 2-6 Graph of Mass Density in Relation to Compression Size 43 0 0 Energy Density Black hole In general, as the energy density increases, the reference frame of the mass shrinks. From its own viewpoint, it is unchanged although at a certain density, some collapse or change of physics as we know it will occur.
Page 1 and 2: 1 The Evans Equations of Unified Fi
Page 3 and 4: 3 Torsion .........................
Page 5: 5 Standard Model with Higgs versus
Page 8 and 9: Do keep in mind Einstein’s statem
Page 10 and 11: postulate of general relativity. In
Page 12 and 13: thought were incorrect. Einstein wa
Page 14 and 15: 8 Figure I-1 Spacetime Newton’s f
Page 16 and 17: In order to do calculations in the
Page 18 and 19: 12 Figure I-4 The Four Forces Gravi
Page 20 and 21: The Particles There are stable, lon
Page 22 and 23: Chapter 1 Special Relativity 16 The
Page 24 and 25: unnoticeable, for low velocities, b
Page 26 and 27: The nature of spacetime is the caus
Page 28 and 29: Figure 1-3 Graph of Stress Energy i
Page 30 and 31: An example is shown in Figure 1-4.
Page 32 and 33: There are many short form abbreviat
Page 34 and 35: The cross product is not defined In
Page 36 and 37: form. Given that they are discrete
Page 38 and 39: curvature, but does not allow spinn
Page 40 and 41: Chapter 2 General Relativity Introd
Page 42 and 43: However, acceleration and a gravita
Page 44 and 45: Energy density reference frames T =
Page 46 and 47: infinity - at distances where the c
Page 50 and 51: Curvature Curvature is central to t
Page 52 and 53: We showed that gravitation is curva
Page 54 and 55: Figure 2-9 Base Manifold with Eucli
Page 56 and 57: In Figure 2-10 at the top is the te
Page 58 and 59: We put the object in the tangent sp
Page 60 and 61: The metric tensor is important in g
Page 62 and 63: Chapter 3 Quantum Theory Quantum Th
Page 64 and 65: 1930’s when it became well establ
Page 66 and 67: that we have such accuracy as we ha
Page 68 and 69: spaces. The formulation is beyond t
Page 70 and 71: frame where measurement is made.) P
Page 72 and 73: Quantum Numbers The equations below
Page 74 and 75: Quantum Gravity and other theories
Page 76 and 77: x time, or momentum x distance, or
Page 78 and 79: 72 E = pc and E = ħ ω and therefo
Page 80 and 81: When the Planck units are used, it
Page 82 and 83: 76 ms is spin quantum number. It is
Page 84 and 85: experiments and to describe events.
Page 86 and 87: are the same space; this is a mathe
Page 88 and 89: 82 If a curve is described by y = a
Page 90 and 91: Scalar, or Inner Product The dot pr
Page 92 and 93: Figure 4-5 Cross Product a 86 The v
Page 94 and 95: product produces surfaces that cut
Page 96 and 97: 4-Vectors and the Scalar Product An
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definite - it is a real distance. I
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Einstein is the tensor defined as G
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With some operations one must add t
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Alternately, a set of basis matrice
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Figure 4-12 100 0 2 1 3 q can repre
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Contravariant and covariant vectors
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The scalars, whether real or imagin
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106 2 _ 1 ∂ 2 c 2 ∂ t 2 can be
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Covariant Exterior Derivative D ∧
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Chapter 5 Well Known Equations Intr
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V = IR. A circuit is a completed ci
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The standard definition of magnetic
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Another way of stating this is that
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Figure 5-4 Ampere's and Faraday’s
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Newton’s law of gravitation 120 A
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Figure 5-6 Fields Poisson’s Equat
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This is a differential operator use
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The Evans equations indicate that R
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Compton and de Broglie wavelengths
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Here ħ = h / 2π = Planck’s cons
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Mathematics and Physics To a certai
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Chapter 6 The Evans Field Equation
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Then the wave equation was develope
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138 q ab µν = q a µq b ν q ab
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From the basic structure of equatio
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142 Rµν - ½ Rgµν = kTµν Eins
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original vector - its orientation i
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The electromagnetic and weak fields
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In more mechanical terms, energy an
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Figure 6-8 Abstract Fiber Bundle an
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The other three fields - electromag
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Figure 6-9 The spin connection and
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Evans Field Equation Extensions R =
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The real physical solutions the wav
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160 Another way to look at the equa
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determined by geometry. This makes
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index, it is generally covariant -
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It is also possible to represent bo
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Electromagnetism 168 The B (3) fiel
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Strong force If tetrad index “a
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neutron into other more stable curv
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explanation for the Aharonov-Bohm a
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ORIGIN Einstein / Hilbert (1915) Ev
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then we found it and used it to des
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Very Strong Equivalence Principle T
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Figure 8-2 Separation of Forces PRI
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Note that physics texts often say t
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criteria for dark matter. We know t
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Figure 8-5 Spinning Spacetime The s
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this gives the influence of gravita
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In all the forms of the tetrad, the
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Spacetime curvature in and around p
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The Evans Wave Equation Figure 8-8
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λ is the wavelength. It can be app
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λde B = ħ / p = ħ / mv (6) where
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where ψ a µ is a tetrad. Therefor
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The components of R = -kT originati
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Relationship between r and λ Profe
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Figure 9-4 Curvature and Wavelength
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One may tentatively assume that the
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The first gives us the Principle of
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Chapter 10 Replacement of the Heise
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p b µ = ћ κ b µ (2) The positio
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The volumes here are derived from V
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The Heisenberg uncertainty principl
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Chapter 11 The Evans B (3) Spin Fie
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where g = e/ћ for one photon; e is
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Figure 11-3 shows the circle turnin
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the curvature very slight at the ea
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The magnetic field components are r
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The B (3) field is the fundamental
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The present standard model uses con
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Using Einstein’s index contracted
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unnecessary and it has been shown t
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Figure 12-4 Momentum Exchange p 3 p
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Figure 12-6 Equations in the Tangen
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were still unknown. However it is o
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Consider an experiment where a beam
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Here κ is wave number, ds is the i
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the Evans unified field theory. Sim
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Figure 13-6 Ordinary Stokes is a ci
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Chapter 14 Geometric Concepts Intro
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where φ is the gravitational poten
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Just what equation will be found to
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where e is the charge of the electr
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have quantization of general relati
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The scalar curvature, R, is defined
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Chapter 15 A Unified Viewpoint Intr
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Asymmetry is a combination of symme
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We know energy density increase is
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G q a µ = kT q a µ. Is one formul
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unknowable measurements. ħ is the
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and their respective ratios was,
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It seems inevitable that we will fi
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Quantum mechanics presented us with
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Evans’ equations the electromagne
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A naïve description would be that
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Note that we are still missing some
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Oscillatory Universe The equation m
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We do not have a definite mechanica
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Glossary There are some terms here
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AIAS Alpha Institute for Advanced S
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The B (3) field and O(3) electrodyn
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The calculations to get coordinates
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Connections Circular Basis The equa
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Elie Cartan worked out an approach
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A covariant component is a physical
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Covariant derivative operator (∇
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Curvature at a given point P has a
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Dimension While mathematically well
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Einstein Field Equation The equatio
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Euclidean spacetime Flat geometric
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Fields explain “action at a dista
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Fundamental Particle A particle wit
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Geometric units Conversion of mass
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describes electrodynamics. It is no
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Index Typically Greek letters are u
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Isomorphism A 1:1 correspondence. J
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Local A very small region of spacet
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Another use is with the Dirac and o
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We want a real number to define the
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Time invariance (or symmetry under
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Dual vectors = one forms = covector
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Meson - Any of a family of subatomi
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The Evans phase law is: This is app
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Quantum gravity Quantum gravity is
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Riemann tensor Riemann calculates t
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Schrodinger's Equation ∇ 2 Ψn =
Page 354 and 355:
The spin connection may be best des
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α angular acceleration; fine struc
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Rotation and reflection of a triang
Page 360 and 361:
Next is O(3) electrodynamics which
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Rank is indicated by the number of
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A spin structure is locally a tetra
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q a µ can be defined in terms of a
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The torsion of a curve is a measure
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our real four dimensional spacetime
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Wave or Quantum Mechanics Study of
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