Unified Theory Of Elementary Particles Research Articles

GAUGE INVARIANCE AND THE GOLDSTONE THEOREM

This paper was originally created for and printed in the "Proceedings of seminar on unified theories of elementary particles" held in Feldafing, Germany from July 5 to 16, 1965 under the auspices of the Max-Planck-Institute for Physics and Astrophysics in Munich. It details and expands upon the 1964 Guralnik, Hagen, and Kibble paper demonstrating that the Goldstone theorem does not require physical zero mass particles in gauge theories.

MEG Studies Prohibited Muon Decays to Explore Grand Unified Theories of Elementary Particles

MEG Studies Prohibited Muon Decays to Explore Grand Unified Theories of Elementary Particles

Planck Scale Physics and Newton's Ultimate Object Conjecture

Abstract According to Newton, the ultimate building blocks of matter are hard frictionless spheres. This conjecture is here analyzed under different assumptions, which are: 1. The ultimate objects of matter are frictionless positive and negative Planck mass particles obeying nonrelativistic Newtonian mechanics. 2. The Planck mass particles interact with the Planck force c 4 /G (c velocity of light, G Newton's constant) locally within a Planck length r p , with the positive Planck mass particles exerting a repulsive and the negative Planck mass particles an attractive force. 3. Space if filled with an equal number of positive and negative Planck mass particles, whereby in the average each Planck length volume occupies one Planck mass particle. Making these three assumptions we derive: 1. Nonrelativistic quantum mechanics as an approximation with departures from this approxima-tion suppressed by the Planck length. 2. Lorentz invariance as a dynamic symmetry for energies small compared to the Plank energy. 3. The operator field equation for the previously proposed Planck aether model of a unified theory of elementary particles. In contrast to theories in which the ultimate objects are strings at the Planck scale, the alternative theory proposed here does not need a higher dimensional space, but rather can be formulated in 3 + 1 dimensions.

The Planck Aether model for a unified theory of elementary particles

A dense assembly of an equal number of two kinds of Planck masses, one having positive and the other one negative kinetic energy, described by a nonrelativistic nonlinear Heisenberg equation with pointlike interactions, is proposed as a model for a unified theory of elementary particles. The dense assembly of Planck masses leads to a vortex field below the Planck scale having the form of a vortex lattice, which can propagate two types of waves, one having the property of Maxwell's electromagnetic and the other one the property of Einstein's gravitational waves. The waves have a cutoff at a wavelength equal to the vortex lattice constant about ∼103 times larger than the Planck length, reproducing the GUT scale of elementary particle physics. The vortex lattice has a resonance energy leading to two kinds of quasiparticles, both of which have the property of Dirac spinors. Depending on the resonance energy, estimated to be ∼107 times smaller than the Planck energy, the mass of one of these quasiparticles is about equal to the electron mass. The mass of the other particle is much smaller, making it a likely candidate for the much smaller neutrino mass. Larger spinor masses occur as internal excitations, with a maximum of four such excitations corresponding to a maximum of four particle families. Other vortex solutions may describe the quark-lepton symmetries of the standard model. All masses, with the exception of the Planck mass particles, are quasiparticles for which Lorentz invariance holds, with the Galilei invariance at the Planck scale dynamically broken into Lorentz invariance below this scale. The assumed equal number of Planck masses with positive and negative kinetic energy makes the cosmological constant exactly equal to zero.

On the Problem of a Finitistic Quantum Field Theory

Abstract A finitistic quantum field theory, as a model for a unified theory of elementary particles is proposed, making the assumption that all spatial and temporal distances can only assume integer values of a fundamental length and time, for which we have chosen the Planck length and Planck time. To satisfy the condition of causality in its quantized version, the theory must be exactly nonrelativistic, because only then can the concept that points in space are separated by multiples of a fundamental length be formulated in an invariant way. The theory is formulated as a partial finite difference equation, invariant under translations and rotations in space, and translations in time, and can be expressed as a partial differential equation of infinite order. The theory is free of all divergencies, has a positive definite metric in Hilbert space and therefore no ghost states. Possessing a fundamental length, chosen to be equal the Planck length, the theory has an inbuilt cut-off at the Planck energy. For energies sufficiently below the Planck energy, the theory can be approximated by the previously described Planck aether model, which can be viewed as a superfluid consisting of Planck masses, leading to special relativity as a dynamic symmetry in the asymptotic limit of low energies.

26. Comments on Yukawa's Nonlocal Field Theory

The theory of non-local field was the result of Yukawa's endeavour to overcome the point model of elementary particles. He believed firmly that the elementary particles are not mathematical point, and tried to introduce a finite extension to them. The motive was on the one hand to obtain a finite theory expecting this extension to work as a kind of cutoff factor, and on the other hand to construct a unified theory of elementary particles by identifying various eigenstates of the internal motion carried by the extended structure with the actual particles. After the completion of the meson theory he concentrated his effort to this problem. But unlike the brilliant success of the meson theory no remarkable success has been obtained at least until now. But I feel that the notion of finite extension still deserve serious study. The revival of the string model on the Planck mass level is one reason. Another reason is the fact that it leads very naturally to the concept of spinor.1> That is because parameter space describing the motion of an extended body is doubly connected. So in this case we have no reason to require that the wave function must be single valued. If we allow double valued wave function half-integer spin eigenvalue is possible, and in fact the eigenfunction of a rigid sphere, for example, belonging to the eigenvalue l =1/2 is just the spinor.2' In view of these it would be of interest to try to seek for a possibility to check the adequacy of Yukawa's idea more directly. For this purpose let us discuss in some detail how to describe the motion of an extended body. Usually it is understood that this can be done by specifying the orientation of a body fixed frame B --the origin of which is assumed to be placed at the center of mass of the body for definiteness-relative to a laboratory fixed frame L. But this is by no means trivial if we consider the possibility that our space-time is curved according to general relativity. This is because in this case we cannot define a line parallel to L through the origin of B. So it is in general impossible to specify the orientation of B relative to L. Therefore, in order to describe the motion of an extended body in conformity with the principle of general relativity, we must specify the orientation of B relative to a reference frame the origin of which is always placed the origin of B. This is kind of gauge philosophy, and leads to a conclusion that if the center of mass of the body is in a motion, L cannot be fixed to the laboratory but must make a parallel displacement along the path of the center of mass of the body in accordance with its motion.

Substratum Approach to a Unified Theory of Elementary Particles

If special relativity is a dynamic symmetry caused by true physical deformations of bodies in absolute motion through a substratum or ether, the question if all interactions and elementary particles arc excitations of this ether must be raised. The ether being the cause of all the observed relativistic effects should then obey an exactly nonrelativistic law of motion, and which permits it to consist of positive and negative masses. The fundamental constants of nature, which according to Planck are 1) Newton's constant (G), 2) the velocity of light (c) and 3) Planck’s constant (ћ), suggest that the ether is made up of densely packed positive and negative Planck masses (Planckions), each with a diameter equaling the Planck length. Symmetry demands that the number of positive and negative Planck masses should be equal, making the cosmological constant equal to zero. Because the Planckions are nonrelativistic spin-zero bosons, the ether would therefore consist of two super­fluids, one for the positive mass Planckions, and the other one for the negative mass Planckions. By spontaneous symmetry breaking this superfluid ether can in its ground state form a lattice of small vortex rings, with the vortex core radius equaling the Planck length. Force fields of massless vector gauge bosons can be interpreted as quantized transverse vortex waves propagating through this lattice. Because the smallest wave length would be about equal the ring radius of the circular vortices, the ring radius would assume the role of a unification scale. The ring radius is estimated to be about 103 times the Planck length, in fairly good agreement with the empirical evidence for the value of the grand unification scale of the standard model. Charge is explained by the zero point fluctuations of the Planckions attached to the vortex rings, wrhich thereby become the source of virtual phonons. Charge quantization is explained as the result of circulation quantization. Spinors result from bound states of the positive and negative masses of the substratum, and special relativity as a dynamic symmetry would be valid for all those objects. Quantum electrodynamics is derived as a low energy approximation If spinors are made up from the positive and negative masses of the vortex ring resonance energy, whereby the spinors would assume the character of excitons, the spinor mass can be computed in terms of the Planck mass. Vice versa, with the lowest quark mass m given, a value for the gravitation­al constant in terms of m, ћ, and c can be obtained. The existence of different particle families can be understood by internal excitations of the spinors, and parity violation may find its explanation in a small nonzero vorticity of the ether. Bacause of its simple fundamental symmetry the theory is unique, it is always finite and has no anomalies. In the proposed theory all fields and interactions are explained in a completely mechanistic way by the Planck masses and their contact interactions. With special relativity as a derived dynamic symmetry and space remaining euclidean, the proposed approach can be seen as an alternative to Einstein’s program to explain all fields and their interactions by symmetries and singularities of a noneuclidean spacetime manifold. In Part I, the fundamental equation for the substratum, which has the form of a nonrelativistic nonlinear Heisenberg equation, is formulated. It is shown how it leads to a Maxwell-type set of equations for the gauge bosons. In Part II, Dirac-type spinors and quantum electrodynamics are derived. These results are then applied to obtain the lowest quark mass in terms of the Planck mass.

Supersymmetry: Kaluza-Klein theory, anomalies, and superstrings

Progress in the search for a unified theory of elementary particles is reviewed. The supersymmetrical Kaluza-Klein theories are described: 11-, 10-, and 6-dimensional models of supergravity. The methods of spontaneous compactification, with whose help the four-dimensional theories are obtained, are described. The properties of the massless sector—zero modes in the Kaluza-Klein theories—and the question of the stability of vacuum solutions are discussed. An important criterion for the selection of a self-consistent theory is the absence of anomalies. The basic formulas for multidimensional chiral and gravitational anomalies are presented. The mechanism of the cancellation of the anomaly for Green and Schwarz's 10-dimensional effective field theory of superstrings with the gauge groups SO(32) and E8 × E8 is described. The basic concepts and the results of the theory of superstrings are presented. This theory has no divergences and is at the present time a very attractive candidate for a unified theory of elementary particles.

Unified Theories of Elementary Particles: Critical Assessment and Prospects: International Symposium in Memory of Werner Heisenberg

Physikalische BlätterVolume 37, Issue 11 p. 347-348 Aus Der WissenschaftOpen Access Unified Theories of Elementary Particles: Critical Assessment and Prospects: International Symposium in Memory of Werner Heisenberg Helmut Rechenberg, Helmut Rechenberg MünchenSearch for more papers by this author Helmut Rechenberg, Helmut Rechenberg MünchenSearch for more papers by this author First published: November 1981 https://doi.org/10.1002/phbl.19810371108AboutPDF ToolsExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinkedInRedditWechat No abstract is available for this article. Volume37, Issue11November 1981Pages 347-348 RelatedInformation

A Unified Theory of Elementary Particles and Forces

A Unified Theory of Elementary Particles and Forces

Vorschlag eines Weges zur einheitlichen Beschreibung der Elementarteilchen / Recommendation of a Way to a Unified Description of Elementary Particles

Abstract This paper presents a concise overview of a voluminous theoretical study whose subject is a unified description of elementary particles. First of all, the empirical basis of the theoretical deliberations is presented and the most promising logical path is explored. Proceeding from equivalence principles and the fact that a unified description of the material world must be a unified theory of elementary particles a path is sketched that leads from a classical gravitation theory and a nonhermitian quantum structure theory to a representation of unified terms in a 6-dimensional carrier space of a Hilbert space. The equivalence of mass terms and the eigenvalue spectrum is then discussed. The necessity of a polymetric structure theory is developed from the cosmogeny of a protouniverse. A further demonstration shows that the consequent realisation of such a polymetric representation allows the separation from the pseudo-continuum of the discrete point spectrum of ponderable mass terms (to be interpreted as elementary particles) of all possible energetic field masses. This provides the desired unified description of the characteristics of the elementary particles. From this description it is evident that these elementary particles appear as final units. Structural characteristics are determined by complicated time expanded inner structures that, among other things, determine radioactive decay. This overview introduces the developmental paths as a work that evidently leads to a unified quantum field theory of matter and gravitation.

The goldstone theorem photons and sommerfeld’s fine-structure constant

The notion of spontaneous breakdown of isospin symmetry as the origin of the photon is investigated in the framework of the unified field theory of elementary particles on the basis of the Goldstone theorem. The treatment evolves towards a particularity of quantum electrodynamics in the hierarchy of interactions. Progress with regard to the problem of unwanted zerons is also reported. An attempt is made to clarify the physical basis of the successes of the unified theory of elementary particles.

Introduction to the Unified theory of elementary particles

Introduction to the Unified theory of elementary particles

Unified theories of elementary particles

THEORISTS AT A RECENT SEMINAR on unified theories of elementary particles were brought together by continued interest in more or less realistic application of quantum field theory to elementaryparticle physics. Thus they do not share the fears of Freeman J. Dyson (expressed in last June's PHYSICS TODAY)—about the relevance of field theory to strong‐interaction physics nor his fear that field theorists are to become an isolated band of specialists like specialists in general relativity.

The Bogoliubov Transformation in the Field Theory

It is confirmed that the method of the Bogoliubov transformation is applicable also in the field theory. The original representation suited for a massless spinor field, ψ(0), can be transformed into another representation, in which the spinor field has a non-zero mass, for the Fermi interactions of any type, by the transformation. But the interaction responsible for the finite mass is the scalar part of the interaction itself or of the equivalent expression obtained by the Fierz transformation. As to the Yukawa interaction, the Bogoliubov transformation must be accompanied by a linear transformation for the Bose field, and the combined transformation is meaningful only for the scalar coupling of a scalar meson with mass. The situation about the φ4 interactions of spinless fields φ is completely the same as in the case of the Fermi interaction, but the method is not applicable to the φ3 interaction of a scalar field. Thus it is suggested that the quantities <<:ψ(0)ψ(0):>> for the Fermi interaction, <<φ(0)>> for the Yukawa interaction, and <<:φ(0)2:>> for the φ4 interactions correspond to the parameter of the long range order in the theory of superconductivity, respectively, where the notatin << >> means the expectation value in the transformed vacuum. It is also shown that Lehmann's method of the spectrum representation can be generalized to treat the canonical transformation, and that it gives a covariant and convenient method to derive the mass equation. In the last section, it is discussed what kinds of image of assumption must be introduced in order that the representation obtained by the Bogoliubov transformation can be used to the unified theories of elementary particles. Counter-examples to the too conventional method used in the theories of spontaneous breakdown of symmetries are also exhibited (§5 and App. I).

An Approach to the Unified Theory of Elementary Particles

A model for elementary particles based on relativistic rotators is considered as a promising approach to a unified theory.

Internal Degrees of Freedom and Elementary Particles. I

Quantum theory of point-like systems is established by extending the concept of relativistic particle in some respects: A point-like system means a one-parameter series of events xp('t) with substantial internal degrees of freedom concentrated upon xP, and indefinite metric in Hilbert space is generally taken as to the internal degrees. The theory corresponds to an extention of the usual local field equations, suitable to obtaining a unified theory of elementary particles. The rest-mass, m2=-p~-'2 (with pP as momentum-energy vector) be­ comes a dynamical quantity of the system with its possible eigenspectrum, leading to un­ certainty relations between rest mass value and space-time localization. The internal angular momentum tensor S pv is another basic dynamical quantity of the system and is responsible for spin and Zitterbewegung. Also defined is the instantaneous velocity operator vP, which is not generally co linear with p P and must be restricted by certain kinematical conditions. Three different criteria about these conditions on v P- make point-like systems classified into various types. For normal class of systems, p=-vP2 is an absolute invariant with eigenvalue 1 or 0 and is regarded to represent baryon number. Especially important are point-like systems of the first kind, i.e. the ones in which vP commute with the position xP and thus mean internal variables. Such a system generally has, besides rest mass, spin and p, three self­ adjoint commuting invariant quantities formed out of pP' vP and Spv only, which are to be identified eventually with the intrinsic properties of elementary particles (isospin, hyper­ charge, etc.). Systems are further divided into classical models, where velocity com­ ponents are commutable (an example being relativistic rotator), and non-classical models where they are not ([vP' vvlrfO), to derive general characteristics for each of them. Dirac and Kemmer particles are special simple examples of the latter, where system has no sub­ stantial internal degrees of freedom apart from v w

Attempts at a Unified Theory of Elementary Particles

Attempts at a Unified Theory of Elementary Particles