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1	An application of the continuity method for an equation on line bundles Gonçalves, Alexandre Casassola. January 2002 (has links) (PDF) Thesis (Ph. D.)--University of Texas at Austin, 2002. / Vita. Includes bibliographical references. Available also from UMI Company. Gauge invariance. Continuity.
2	An application of the continuity method for an equation on line bundles Gonçalves, Alexandre Casassola 28 August 2008 (has links) Not available / text Gauge invariance Continuity
3	Operator Gauge Transformations in Nonrelativistic Quantum Electrodynamics Gray, Raymond Dale 12 1900 (has links) A system of nonrelativistic charged particles and radiation is canonically quantized in the Coulomb gauge and Maxwell's equations in quantum electrodynamics are derived. By requiring form invariance of the Schrodinger equation under a space and time dependent unitary transformation, operator gauge transformations on the quantized electromagnetic potentials and state vectors are introduced. These gauge transformed potentials have the same form as gauge transformations in non-Abelian gauge field theories. A gauge-invariant method for solving the time-dependent Schrodinger equation in quantum electrodynamics is given. Maxwell's equations are written in a form which holds in all gauges and which has formal similarity to the equations of motion of non-Abelian gauge fields. A gauge-invariant derivation of conservation of energy in quantum electrodynamics is given. An operator gauge transformation is made to the multipolar gauge in which the potentials are expressed in terms of the electromagnetic fields. The multipolar Hamiltonian is shown to be the minimally coupled Hamiltonian with the electromagnetic potentials in the multipolar gauge. The model of a charged harmonic oscillator in a single-mode electromagnetic field is considered as an example. The gauge-invariant procedure for solving the time-dependent Schrodinger equation is used to obtain the gauge-invariant probabilities that the oscillator is in an energy eigenstate For comparison, the conventional approach is also used to solve the harmonic oscillator problem and is shown to give gauge-dependent amplitudes. quantum electrodynamics gauge invariance Schrödinger equation Quantum electrodynamics. Gauge invariance.
4	Test of Gauge Invariance: Charged Harmonic Oscillator in an Electromagnetic Field Wen, Chang-tai 08 1900 (has links) The gauge-invariant formulation of quantum mechanics is compared to the conventional approach for the case of a one-dimensional charged harmonic oscillator in an electromagnetic field in the electric dipole approximation. The probability of finding the oscillator in the ground state or excited states as a function of time is calculated, and the two approaches give different results. On the basis of gauge invariance, the gauge-invariant formulation of quantum mechanics gives the correct probability, while the conventional approach is incorrect for this problem. Therefore, expansion coefficients or a wave function cannot always be interpreted as probability amplitudes. For a physical interpretation as probability amplitudes the expansion coefficients must be gauge invariant. gauge invariance charged harmonic oscillator Gauge invariance.
5	Semiclassical monopole calculations in supersymmetric gauge theories Davies, N. Michael January 2000 (has links) We investigate semiclassical contributions to correlation functions in N = 1 supersymmetric gauge theories. Our principal example is the gluino condensate, which signals the breaking of chiral symmetry, and should be exactly calculable, according to a persymmetric non-renormalisation theorem. However, the two calculational approaches previously employed, SCI and WCI methods, yield different values of the gluino condensate. We describe work undertaken to resolve this discrepancy, involving a new type of calculation in which the space is changed from R(^4) to the cylinder R(3) x S(1) This brings control over the coupling, and supersymmetry ensures that we are able to continue to large radii and extract answers relevant to R(^4). The dominant semiclassical configurations on the cylinder are all possible combinations of various types of fundamental monopoles. One specific combination is a periodic instanton, so monopoles are the analogue of the instanton partons that have been conjectured to be important at strong coupling. Other combinations provide significant contributions that are neglected in the SCI approach. Monopoles are shown to generate a superpotential that determines the quantum vacuum, where the theory is confining. The gluino condensate is calculated by summing the direct contributions from all fundamental monopoles. It is found to be in agreement with the WCI result for any classical gauge group, whereas the values for the exceptional groups have not been calculated before. The ADS superpotential, which describes the low energy dynamics of matter in a supersymmetric gauge theory, is derived using monopoles for all cases where instantons do not contribute. We report on progress made towards a two monopole calculation, in an attempt to quantify the missed contributions of the SCI method. Unfortunately, this eventually proved too complicated to be feasible. 530.1
6	The simplest gauge-string duality Nkumane, Lwazi Khethukuthula January 2015 (has links) A dissertation submitted to the University of the Witwatersrand, Faculty of Science in ful lment of the academic requirements of the degree of Master of Science. Johannesburg, 2015. / The gauge/gravity correspondence is a conjectured exact duality between quantum eld theories and theories of quantum gravity. A very simple gauge/string duality, claims an equivalence between the Gaussian matrix model and the topological A-model string theory on P1. In this dissertation we study this duality, proposing concrete operators in the matrix model that are dual to gravitational descendants of the puncture operator of the topological string theory. We test our proposal by showing that a large number of matrix model correlators are in complete agreement with correlators in the dual topological string theory. Contact term interactions, as proposed by Gopakumar and Pius, play an interesting and non-trivial role in the duality. Gravitation. Quantum gravity. Quantum field theory. Gauge invariance.
7	Memory in non-Abelian gauge theory Gadjagboui, Bourgeois Biova Irenee January 2017 (has links) A research project submitted to the Faculty of Science, University of the Witwatersrand, in fulﬁllment for the degree of Master of Science in Physics. May 25, 2017. / This project addresses the study of the memory eﬀect. We review the eﬀect in electromagnetism, which is an abelian gauge theory. We prove that we can shift the phase factor by performing a gauge transformation. The gauge group is U(1). We extend the study to the nonabelian gauge theory by computing the memory in SU(2) which vanishes up to the ﬁrst order Taylor expansion. Keywords: Memory Eﬀect, Aharonov-Bohm eﬀect, Nonabelian Gauge Theory, Supersymmetry / GR2018 Gauge fields (Physics)--Mathematics Gauge invariance Abelian groups
8	On a grouptheoretical approach to gauge invariance of massive spin-one free fields in the infinite-momentum limit Chakravorty, Nripendra Nath 05 1900 (has links) No description available. Field theory (Physics) Gauge fields (Physics) Gauge invariance
9	On the Cauchy problem for the linearized GPKdV and gauge transformations for a quadratic pencil and AKNS system / Yordanov, Russi Georgiev, January 1992 (has links) Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1992. / Vita. Abstract. Includes bibliographical references (leaves 52-54). Also available via the Internet.
10	A Gauge-Invariant Energy Variational Principle Application to Anisotropic Excitons in High Magnetic Fields Kennedy, Paul K. (Paul Kevin) 12 1900 (has links) A new method is developed for treating atoms and molecules in a magnetic field in a gauge-invariant way using the Rayleigh-Ritz energy variational principle. The energy operator depends on the vector potential which must be chosen in some gauge. In order to adapt the trial wave function to the gauge of the vector potential, the trial wave function can be multiplied by a phase factor which depends on the spatial coordinates. When the energy expectation value is minimized with respect to the phase function, the equation for charge conservation for stationary states is obtained. This equation can be solved for the phase function, and the solution used in the energy expectation value to obtain a gauge-invariant energy. The method is applicable to all quantum mechanical systems for which the variational principle can be applied. It ensures satisfaction of the charge conservation condition, a gauge-invariant energy, and the best upper bound to the ground-state energy which can be obtained for the form of trial wave function chosen. gauge variance magnetic fields Exciton theory Exciton theory. Gauge invariance.

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