Generally Covariant Quantum Mechanics



Similar documents
Orbital Dynamics in Terms of Spacetime Angular Momentum

MASTER OF SCIENCE IN PHYSICS MASTER OF SCIENCES IN PHYSICS (MS PHYS) (LIST OF COURSES BY SEMESTER, THESIS OPTION)

Theory of electrons and positrons

Chemical shift, fine and hyperfine structure in RFR spectroscopy

PHYS 1624 University Physics I. PHYS 2644 University Physics II

DO PHYSICS ONLINE FROM QUANTA TO QUARKS QUANTUM (WAVE) MECHANICS

THE MEANING OF THE FINE STRUCTURE CONSTANT

Three Pictures of Quantum Mechanics. Thomas R. Shafer April 17, 2009

1 Lecture 3: Operators in Quantum Mechanics

Does Quantum Mechanics Make Sense? Size

Physics 9e/Cutnell. correlated to the. College Board AP Physics 1 Course Objectives

arxiv:quant-ph/ v1 22 Apr 2004

Losing energy in classical, relativistic and quantum mechanics

Unamended Quantum Mechanics Rigorously Implies Awareness Is Not Based in the Physical Brain

2. Spin Chemistry and the Vector Model

DO WE REALLY UNDERSTAND QUANTUM MECHANICS?

PX408: Relativistic Quantum Mechanics

The Quantum Harmonic Oscillator Stephen Webb

Chapter 18: The Structure of the Atom

Concepts in Theoretical Physics

It Must Be Beautiful: Great Equations of Modern Science CONTENTS The Planck-Einstein Equation for the Energy of a Quantum by Graham Farmelo E = mc 2

White Dwarf Properties and the Degenerate Electron Gas

Special Theory of Relativity

Till now, almost all attention has been focussed on discussing the state of a quantum system.

Where is Fundamental Physics Heading? Nathan Seiberg IAS Apr. 30, 2014

Wave Function, ψ. Chapter 28 Atomic Physics. The Heisenberg Uncertainty Principle. Line Spectrum

Chapter 22 The Hamiltonian and Lagrangian densities. from my book: Understanding Relativistic Quantum Field Theory. Hans de Vries

Assessment Plan for Learning Outcomes for BA/BS in Physics

How Fundamental is the Curvature of Spacetime? A Solar System Test. Abstract

What does Quantum Mechanics tell us about the universe?

PHYSICS FOUNDATIONS SOCIETY THE DYNAMIC UNIVERSE TOWARD A UNIFIED PICTURE OF PHYSICAL REALITY TUOMO SUNTOLA

A Theory for the Cosmological Constant and its Explanation of the Gravitational Constant

The integrating factor method (Sect. 2.1).

The Essence of Gravitational Waves and Energy

Journal of Engineering Science and Technology Review 2 (1) (2009) Lecture Note

STRING THEORY: Past, Present, and Future

DOCTOR OF PHILOSOPHY IN PHYSICS

Time dependence in quantum mechanics Notes on Quantum Mechanics

Commentary on Sub-Quantum Physics

3-9 EPR and Bell s theorem. EPR Bohm s version. S x S y S z V H 45

Electrostatic Fields: Coulomb s Law & the Electric Field Intensity

Orbits of the Lennard-Jones Potential

Gauge theories and the standard model of elementary particle physics

Evaluation of Quantitative Data (errors/statistical analysis/propagation of error)

Derivation of the relativistic momentum and relativistic equation of motion from Newton s second law and Minkowskian space-time geometry

The Role of Electric Polarization in Nonlinear optics

Mathematics Course 111: Algebra I Part IV: Vector Spaces

DISTANCE DEGREE PROGRAM CURRICULUM NOTE:

Atomic Structure: Chapter Problems

Pre-requisites

Nmv 2 V P 1 3 P 2 3 V. PV 2 3 Ne kin. 1. Kinetic Energy - Energy of Motion. 1.1 Kinetic theory of gases

Quantum Phenomena and the Theory of Quantum Mechanics

Basic Nuclear Concepts

Recent developments in Electromagnetic Hadron Form Factors

Nanoelectronics. Chapter 2 Classical Particles, Classical Waves, and Quantum Particles. Q.Li@Physics.WHU@2015.3

Precession of spin and Precession of a top

The Physics Degree. Graduate Skills Base and the Core of Physics

13- What is the maximum number of electrons that can occupy the subshell 3d? a) 1 b) 3 c) 5 d) 2

Quantum Mechanics and Representation Theory

What are Scalar Waves?

Journal of Theoretics Journal Home Page

A Modest View of Bell s Theorem. Steve Boughn, Princeton University and Haverford College

AP1 Electricity. 1. A student wearing shoes stands on a tile floor. The students shoes do not fall into the tile floor due to

Physics. Overview. Requirements for the Major. Requirements for the Minor. Teacher Licensure. Other. Credits. Credits. Courses. Courses.

Particle Physics. Michaelmas Term 2011 Prof Mark Thomson. Handout 7 : Symmetries and the Quark Model. Introduction/Aims

APPLICATIONS OF TENSOR ANALYSIS

State of Stress at Point

P.A.M. Dirac Received May 29, 1931

The Einstein field equations

Lessons on Teaching Undergraduate General Relativity and Differential Geometry Courses

5.61 Physical Chemistry 25 Helium Atom page 1 HELIUM ATOM

Name Date Class ELECTRONS IN ATOMS. Standard Curriculum Core content Extension topics

arxiv: v1 [physics.gen-ph] 17 Sep 2013

ABSTRACT. We prove here that Newton s universal gravitation and. momentum conservation laws together reproduce Weinberg s relation.

How To Understand Light And Color

Time and Causation in Gödel s Universe.

Feynman diagrams. 1 Aim of the game 2

FLAP P11.2 The quantum harmonic oscillator

Operator methods in quantum mechanics

Is quantum mechanics compatible with a deterministic universe? Two interpretations of quantum probabilities *

PHY4604 Introduction to Quantum Mechanics Fall 2004 Practice Test 3 November 22, 2004

Fernanda Ostermann Institute of Physics, Department of Physics, Federal University of Rio Grande do Sul, Brazil.

Some Comments on the Derivative of a Vector with applications to angular momentum and curvature. E. L. Lady (October 18, 2000)

European Benchmark for Physics Bachelor Degree

Introduction to SME and Scattering Theory. Don Colladay. New College of Florida Sarasota, FL, 34243, U.S.A.

ORDINARY DIFFERENTIAL EQUATIONS

WHAT ARE MATHEMATICAL PROOFS AND WHY THEY ARE IMPORTANT?

2.3. Finding polynomial functions. An Introduction:

Online Courses for High School Students

On a Flat Expanding Universe

Newton s Laws of Motion

The quantum mechanics of particles in a periodic potential: Bloch s theorem

Transcription:

Chapter 15 Generally Covariant Quantum Mechanics by Myron W. Evans, Alpha Foundation s Institutute for Advance Study (AIAS). (emyrone@oal.com, www.aias.us, www.atomicprecision.com) Dedicated to the Late Jean-Pierre Vigier Abstract In order to make quantum mechanics compatible with general relativity the Heisenberg uncertainty principle is given a generally covariant (or objective) and causal interpretation. The fundamental conjugate variables are shown to be quantities such as momentum density, angular momentum density and energy density in general relativity instead of quantities such as momentum, angular momentum and energy in special relativity. The generally covariant interpretation of quantum mechanics given in this paper agrees with the repeatable and reproducible experimental data of Croca et al. and of Afshar, data which show that the conventional Heisenberg uncertainty principle is qualitatively incorrect, and with it all the arguments of the Copenhagen school throughout the twentieth century. The correctly objective interpretation of quantum mechanics is given by the deterministic school of Einstein, de Broglie, Vigier and others. This is a direct result of the Evans unified field theory. Key words: Evans unified field theory; generally covariant Heisenberg equation and Heisenberg uncertainty principle. 163

15.1. INTRODUCTION 15.1 Introduction Generally covariant quantum mechanics does not exist in the standard model because general relativity is causal and objective, the Copenhagen interpretation of quantum mechanics is acausal and subjective. This is the central issue of the great twentieth century debate in physics between the Copenhagen and deterministic schools of thought, an issue which is resolved conclusively in favor of the deterministic school by the Evans unified field theory [1] [19]. At the root of the debate is the Heisenberg equation of motion [20], which in its simplest form is a rewriting of the operator equivalence condition of quantum mechanics: Eq.(15.1) is an equation of special relativity where: ( ) En p µ = c, p p µ = i µ. (15.1) (15.2) is the energy momentum four vector, and: ( ) 1 µ = c t,. (15.3) Here En denotes energy, c is the vacuum speed of light, p is the linear momentum, is the reduced Planck constant, and the partial four derivative µ is defined in terms of the time derivative and the operator in Eq.(15.3). In Section 15.2 the operator equivalence (15.1) is rewritten as the Heisenberg equation of motion [20]. The Heisenberg uncertainty principle is a direct mathematical consequence of the Heisenberg equation and therefore is a direct mathematical consequence of Eq.(15.1). However, recent reproducible and repeatable experimental data [21] [23] show that the Heisenberg uncertainty principle is violated completely in several independent ways. This means that the principle as it stands is completely incorrect, i.e. by many orders of magnitude. For example in the various experiments of Croca et al. [21] the principle is incorrect by nine orders of magnitude even at moderate microscope resolution. As the resolution is increased it becomes qualitatively wrong, i.e. the conjugate variable of position and momentum appear to commute precisely within experimental precision. The uncertainty principle states that if the conjugate variables are for example the position x and the component p x of linear momentum then [20]: δxδp x 2. (15.4) This means that the δx and δp x variables cannot commute and the conventional Copenhagen interpretation is that they cannot be simultaneously observable [20] and cannot be simultaneously knowable. This subjective assertion violates causality and general relativity (i.e. objective physics) and has led to endless confusion for students. The experimental results of Croca et al [21] show that: δxδp x = 10 9 2 (15.5) 164

CHAPTER 15. GENERALLY COVARIANT QUANTUM MECHANICS at moderate microscope resolution. As the latter is increased, the experimental result is: δxδp x 0 (15.6) in direct experimental contradiction of the uncertainty principle (15.4). In the independent series of experiments by Afshar [22], carried out at Harvard and elsewhere, the photon and electromagnetic wave are shown to be simultaneously observable, indicating independently that the position and momentum or time and energy conjugate variables commute precisely to within experimental precision. In a third series of independent experiments [23], on two dimensional materials near absolute zero, the Heisenberg uncertainty principle again predicts diametrically the incorrect experimental result to within instrumental precision. Each type of experiment [21] [23] is independently reproducible and repeatable to high precision. In Section 15.3 this major crisis for the standard model is resolved straightforwardly through the use of the appropriate densities of conjugate variables in general relativity. The experimentally well tested Eq.(15.1) is retained, but the fundamental conjugate variables are carefully redefined within the generally covariant Evans unified field theory, which derives generally covariant quantum mechanics from Cartans differential geometry [1] [19] for all radiated and matter fields. The result is a generally covariant quantum mechanics in agreement with the most recent experiments [21] [23] and philosophically compatible with the causal and objective Evans unified field theory. The latter denies subjectivity and acausality in natural philosophy. 15.2 A Simple Derivation Of The Heisenberg Equation Of Motion In its simplest form the Heisenberg equation of motion [20] is: [x, p x ] ψ = i ψ (15.7) where ψ is the wave-function. Eq.(15.7) means that the commutator: operates on the wave-function. From Eq.(15.1): [x, p x ] = xp x p x x (15.8) p x = i x (15.9) and so p x becomes a differential operator acting on ψ. The position x is interpreted as a simple multiple, i.e. x multiplies anything that follows it. Using 165

15.3. THE GENERALLY COVARIANT HEISENBERG EQUATION the Leibnitz Theorem and these operator rules it follows that: [x, p x ] ψ = (xp x p x x) ψ = x (p x ψ) p x (xψ) = x (p x ψ) (p x x) ψ x (p x ψ) = (p x x) ψ ( = i x ) ψ x = i ψ (15.10) and it is seen that the Heisenberg equation is a rewriting of Eq.(15.1), a component of which is Eq.(15.9). Using standard methods [20] we obtain the famous Heisenberg uncertainty principle δxδp x 2 (15.11) from Eq.(15.9) and thus from Eq.(15.1), the famous wave particle duality of de Broglie. This derivation is given to show that the uncertainty principle, which has dominated thought in physics for nearly a century, is another statement of the de Broglie wave particle duality. The subjective and acausal interpretations inherent in the Heisenberg uncertainty principle were rejected immediately by Einstein and his followers, as is well known, and later also rejected by de Broglie and his follower Vigier. These are the acknowledged masters of the deterministic school of physics in the twentieth century. The data [21] [23] now show with pristine clarity that the deterministic school is right, the Copenhagen school is wrong. It is important to realize that the deterministic school accepts quantum mechanics, i.e accepts Eq.(15.1) but rejects the INTERPRETATION of Eq.(15.7) by the Copenhagen school. The ensuing debate became protracted due to a lack of a unified field theory and a lack of experimental data. Both are now available. 15.3 The Generally Covariant Heisenberg Equation Neither school discovered the reason why Eq.(15.11) is so wildly incorrect. With the emergence of the Evans unified field theory (2003 to present), more than a hundred years after special relativity (1892-1905), we now know why the experiments [21] [23] give the results they do. The error in the Copenhagen school s philosophy is the obvious one - the subjective reliance on conjugate variables which are not correctly objective (generally covariant). They are not DENSITIES, as required by the fundamentals of general relativity and the Evans unified field theory. In order to develop a correctly objective quantum mechanics the momentum p x has to be replaced by a momentum density p x and the angular 166

CHAPTER 15. GENERALLY COVARIANT QUANTUM MECHANICS momentum by an angular momentum density. fundamental law of general relativity [1] [19] is: The reason is that the R = kt (15.12) where T is the scalar valued canonical energy-momentum density, R is a well defined scalar curvature, and k is Einstein s constant. In the rest frame T reduces to the mass density of an elementary particle: and within a factor c 2 this is the rest energy density: Here V 0 is the Evans rest volume T m V 0 (15.13) En 0 = mc2 V 0. (15.14) V 0 = 2 k mc 2 (15.15) where m is the elementary particle mass. Define the experimental momentum density for a given instrument by: p x = p x V and define the fundamental angular momentum or action density by: (15.16) = V 0. (15.17) Here V is a macroscopic volume defined by the apparatus being used, or the volume occupied by the momentum component p x. The quantum is the fundamental density of the reduced Planck constant: = mc2 k (15.18) i.e. the rest energy divided by the product of and k. Eq(15.18) means that the quantum of action occupies the Evans rest volume V 0. For any particle, including the six quarks, the photon and the neutrinos, the graviton and the gravitino. This deduction follows from the special relativistic limit of the Evans wave equation for one particle is [1] [19]: In general relativity therefore Eq.(15.9) becomes: kt = km V 0 = m2 c 2 2. (15.19) p x = i x (15.20) 167

15.3. THE GENERALLY COVARIANT HEISENBERG EQUATION i.e.: p x ψ = i ψ x. (15.21) Eq.(15.9), which is precisely verified experimentally in quantum mechanics, is therefore the same as: p x = i V 0 V (15.22) x which is a special case of the fundamental wave particle duality in general relativity: p µ = i V 0 V µ. (15.23) The generally covariant Heisenberg equation is therefore: [x, p x ] = i V 0 V (15.24) and the fundamental conjugate variables of generally covariant quantum mechanics are x and p x. The fundamental quantum is. Experimentally for a macroscopic volume V : V 0 V (15.25) and so which implies [x, p x ] 0 (15.26) δx 0, δp x 0 (15.27) is quite possible experimentally. Therefore what is being observed experimentally in the Croca and Afshar experiments is p x and not p x, and and not. This deduction means that a particle coexists with its matter wave, as inferred by de Broglie. For electromagnetism this coexistence has been clearly observed by Afshar [22] in modified Young experiments which are precise, reproducible and repeatable. The fundamental conjugate variables are therefore position and momentum density, or time and energy density, and not position and momentum, or time and energy as in the conventional theory [20] and as in the Copenhagen interpretation. The wave function is always the tetrad, and this is always defined causally and objectively by Cartans differential geometry [1] [19]. There is no uncertainty or acausality in geometry and none in physics. The fundamental wave equation of generally covariant quantum mechanics is the Evans wave equation [1] [19]: ( + kt ) q a µ = 0 (15.28) which reduces to all other wave equations of physics, and thence to other equations of physics in well defined limits. 168

CHAPTER 15. GENERALLY COVARIANT QUANTUM MECHANICS Acknowledgments The British Government is thanked for a Civil List Pension. Franklin Amador is thanked for meticulous typesetting. Sean MacLachlan and Bob Gray are thanked for setting up the websites www.aias.us and www.atomicprecision.com. The Ted Annis Foundation, Craddock Inc, Prof. John B. Hart and several others are thanked for funding. The staff of AIAS and many others are thanked for many interesting discussions, 2003 to present. 169

15.3. THE GENERALLY COVARIANT HEISENBERG EQUATION 170

Bibliography [1] M. W. Evans, Found. Phys. Lett., 16, 367, 507 (2003). [2] M. W. Evans, Found. Phys. Lett., 17, 25, 149, 267, 301, 393, 433, 535, 663 (2004). [3] M. W. Evans, Found. Phys. Lett., 18, 259 (2005). [4] M. W. Evans, Generally Covariant Unified Field Theory: the Geometrization of Physics (in press 2005, preprints on www.aias.us and [5] L. Felker, The Evans Equations of Unified Field Theory (in press 2005, preprints on www.aias.us and [6] M. W. Evans, The Objective Laws of Classical Electrodynamics, the Effect of Gravitation on Electromagnetism, J. New Energy Special Issue (2005, preprint on www.aias.us and [7] M. W. Evans, First and Second Order Aharonov Bohm Effects in the Evans Unified Field Theory, J. New Energy Special Issue (2005, preprint on www.aias.us and [8] M. W. Evans, The Spinning of Spacetime as Seen in the Inverse Faraday Effect, J. New Energy Special Issue (2005, preprint on www.aias.us and [9] M. W. Evans, On the Origin of Polarization and Magnetization, J. New Energy Special Issue (2005, preprint on www.aias.us and [10] M. W. Evans, Explanation of the Eddington Experiment in the Evans Unified Field Theory, J. New Energy Special Issue (2005, preprint on www.aias.us and [11] M. W. Evans, The Coulomb and Ampère Maxwell Laws in the Schwarzschild Metric: A Classical Calculation of the Eddington Effect from the Evans Field Theory, J. New Energy Special Issue (2005, preprint on www.aias.us and 171

BIBLIOGRAPHY [12] M. W. Evans, Generally Covariant Heisenberg Equation from the Evans Unified Field Theory, J. New Energy Special Issue (2005, preprint on www.aias.us and [13] M. W. Evans, Metric Compatibility and the Tetrad Postulate, J. New Energy Special Issue (2005, preprint on www.aias.us and [14] M. W. Evans. Derivation of the Evans Lemma and Wave Equation from the First Cartan Structure Equation, J. New Energy Special Issue (2005, preprint on www.aias.us and [15] M. W. Evans, Proof of the Evans Lemma from the Tetrad Postulate, J. New Energy Special Issue (2005, preprint on www.aias.us and [16] M. W. Evans, Self-Consistent Derivation of the Evans Lemma and Application to the Generally Covariant Dirac Equation, J. New Energy Special Issue (2005, preprint on www.aias.us and [17] M. W. Evans, Quark Gluon Model in the Evans Unified Field Theory, J. New Energy Special Issue (2005, preprint on www.aias.us and [18] M. W. Evans, The Origin of Intrinsic Spin and the Pauli Exclusion Principle in the Evans Unified Field Theory, J. New Energy Special Issue (2005, preprint on www.aias.us and [19] M. W. Evans, On the Origin of Dark Matter as Spacetime Torsion, J. New Energy Special Issue (2005, preprint on www.aias.us and [20] P. W. Atkins, Molecular Quantum Mechanics (Oxford Univ Press, 2nd ed., 1983). [21] J. R. Croca, Towards a Non-Linear Quantum Physics (World Scientific, 2003). [22] M. Chown, New Scientist, 183, 30 (2004). [23] B. Schechter, New Scientist, pp.38 ff (2004). 172

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information