51 results on '"Quantization (physics)"'
Search Results
2. Quantizations of the classical time of arrival and their dynamics.
- Author
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Galapon, Eric A. and P. Magadan, John Jaykel
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QUANTIZATION (Physics) , *EIGENFUNCTIONS , *EIGENVALUES , *POLYNOMIALS , *OPERATOR theory - Abstract
Abstract The classical time of arrival in the interacting case is quantized by way of quantizing its expansion about the free time of arrival. The quantization is formulated in coordinate representation which represents ordering rules in terms of two variable polynomial functions. This leads to representations of the quantized time of arrival operators as integral operators whose kernels are determined by the chosen ordering rule. The formulation lends itself to generalization which allows construction of time of arrival operators that cannot be obtained by direct quantization using particular ordering rules. Weyl, symmetric and Born–Jordan quantizations are specifically studied. The dynamics of the eigenfunctions of the different time of arrival operators are investigated. The eigenfunctions exhibit unitary arrival at the intended arrival point at their respective eigenvalues. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
3. Equivalence of Einstein and Jordan frames in quantized anisotropic cosmological models.
- Author
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Pandey, Sachin, Banerjee, Narayan, and Pal, Sridip
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ANISOTROPY , *QUANTUM cosmology , *MATHEMATICAL analysis , *QUANTIZATION (Physics) , *SCALAR field theory - Abstract
The present work shows that the mathematical equivalence of the Jordan frame and its conformally transformed version, the Einstein frame, so as far as Brans–Dicke theory is concerned, survives a quantization of cosmological models, arising as solutions to the Brans–Dicke theory. We work with the Wheeler–deWitt quantization scheme and take up quite a few anisotropic cosmological models as examples. We effectively show that the transformation from the Jordan to the Einstein frame is a canonical one and hence two frames furnish equivalent description of same physical scenario. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
4. Three examples of quantum dynamics on the half-line with smooth bouncing.
- Author
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Almeida, C.R., Bergeron, H., Gazeau, J.-P., and Scardua, A.C.
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QUANTUM theory , *COHERENT states , *QUANTIZATION (Physics) , *SYMMETRY (Physics) , *HOMOGENEOUS spaces - Abstract
This article is an introductory presentation of the quantization of the half-plane based on affine coherent states (ACS). The half-plane carries a natural affine symmetry, i.e. it is a homogeneous space for the 1d-affine group, and it is viewed as the phase space for the dynamics of a positive physical quantity evolving with time. Its affine symmetry is preserved due to the covariance of this type of quantization. We promote the interest of such a procedure for transforming a classical model into a quantum one, since the singularity at the origin is systematically removed, and the arbitrariness of boundary conditions for the Schrödinger operator can be easily overcome. We explain some important mathematical aspects of the method. Three elementary examples of applications are presented, the quantum breathing of a massive sphere, the quantum smooth bouncing of a charged sphere, and a smooth bouncing of “dust” sphere as a simple model of quantum Newtonian cosmology. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
5. Dynamical aspects in the quantizer–dequantizer formalism.
- Author
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Ciaglia, F.M., Di Cosmo, F., Ibort, A., and Marmo, G.
- Subjects
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QUANTIZATION (Physics) , *QUANTUM mechanics , *QUANTUM states , *COHERENT states , *WEYL'S problem - Abstract
The use of the quantizer–dequantizer formalism to describe the evolution of a quantum system is reconsidered. We show that it is possible to embed a manifold in the space of quantum states of a given auxiliary system by means of an appropriate quantizer–dequantizer system. If this manifold of states is invariant with respect to some unitary evolution, the quantizer–dequantizer system provides a classical-like realization of such dynamics, which in general is non linear. Integrability properties are also discussed. Weyl systems and generalized coherent states are used as a simple illustration of these ideas. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
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6. Gauged Floreanini–Jackiw type chiral boson and its BRST quantization.
- Author
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Rahaman, Anisur and Yasmin, Safia
- Subjects
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GAUGE field theory , *CHIRALITY of nuclear particles , *BOSONS , *INVARIANTS (Mathematics) , *QUANTIZATION (Physics) - Abstract
The gauged model of Siegel type chiral boson is considered. It has been shown that the action of gauged model of Floreanini–Jackiw (FJ) type chiral boson is contained in it in an interesting manner. A BRST invariant action corresponding to the action of gauged FJ type chiral boson has been formulated using Batalin, Fradkin and Vilkovisky based improved Fujiwara, Igarishi and Kubo (FIK) formalism. An alternative quantization of the gauge symmetric action has been made with a Lorentz gauge and an attempt has been made to establish the equivalence between the gauge symmetric version of the extended phase space and original gauge non-invariant version of the usual phase space. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
7. Foundations of Quantum Mechanics: Derivation of a dissipative Schrödinger equation from first principles.
- Author
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Gonçalves, L.A. and Olavo, L.S.F.
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QUANTUM mechanics , *SCHRODINGER equation , *ENERGY dissipation , *QUANTIZATION (Physics) , *HAMILTONIAN mechanics , *CLASSICAL mechanics - Abstract
Dissipation in Quantum Mechanics took some time to become a robust field of investigation after the birth of the field. The main issue hindering developments in the field is that the Quantization process was always tightly connected to the Hamiltonian formulation of Classical Mechanics. In this paper we present a quantization process that does not depend upon the Hamiltonian formulation of Classical Mechanics (although still departs from Classical Mechanics) and thus overcome the problem of finding, from first principles, a completely general Schrödinger equation encompassing dissipation. This generalized process of quantization is shown to be nothing but an extension of a more restricted version that is shown to produce the Schrödinger equation for Hamiltonian systems from first principles (even for Hamiltonian velocity dependent potential). [ABSTRACT FROM AUTHOR]
- Published
- 2017
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8. Black hole as a magnetic monopole within exponential nonlinear electrodynamics.
- Author
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Kruglov, S.I.
- Subjects
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MAGNETIC monopoles , *ELECTRODYNAMICS , *COVARIANT field theories , *QUANTIZATION (Physics) , *PHASE transitions - Abstract
We perform the gauge covariant quantization of the exponential model of nonlinear electrodynamics. Magnetically charged black holes, in the framework of our model are considered, and the regular black hole solution is obtained in general relativity. The asymptotic black hole solution at r → ∞ is found. We calculate the magnetic mass of the black hole and the metric function which are expressed via the parameter β of the model and the magnetic charge. The thermodynamic properties and thermal stability of regular black holes are analysed. We calculate the Hawking temperature of black holes and their heat capacity at the constant magnetic charge. We find a point where the temperature changes the sign that corresponds to the first-order phase transition. It is shown that at critical point, where the heat capacity diverges, there is a phase transition of the second-order. We obtain the parameters of the model when the black hole is stable. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
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9. Riemann surface and quantization.
- Author
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Perepelkin, E.E., Sadovnikov, B.I., and Inozemtseva, N.G.
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RIEMANN surfaces , *QUANTIZATION (Physics) , *MATHEMATICAL complex analysis , *DIRAC function , *BOHMIAN mechanics - Abstract
This paper proposes an approach of the unified consideration of classical and quantum mechanics from the standpoint of the complex analysis effects. It turns out that quantization can be interpreted in terms of the Riemann surface corresponding to the multivalent L n Ψ function. A visual interpretation of “trajectories” of the quantum system and of the Feynman’s path integral is presented. A magnetic dipole having a magnetic charge that satisfies the Dirac quantization rule was obtained. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
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10. Dirac fields in flat FLRW cosmology: Uniqueness of the Fock quantization.
- Author
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Cortez, Jerónimo, Elizaga Navascués, Beatriz, Martín-Benito, Mercedes, Mena Marugán, Guillermo A., and Velhinho, José M.
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DIRAC equation , *FOCK spaces , *METAPHYSICAL cosmology , *UNIQUENESS (Mathematics) , *QUANTIZATION (Physics) , *SYMMETRY (Physics) - Abstract
We address the issue of the infinite ambiguity that affects the construction of a Fock quantization of a Dirac field propagating in a cosmological spacetime with flat compact sections. In particular, we discuss a physical criterion that restricts to a unique possibility (up to unitary equivalence) the infinite set of available vacua. We prove that this desired uniqueness is guaranteed, for any possible choice of spin structure on the spatial sections, if we impose two conditions. The first one is that the symmetries of the classical system must be implemented quantum mechanically, so that the vacuum is invariant under the symmetry transformations. The second and more important condition is that the constructed theory must have a quantum dynamics that is implementable as a (non-trivial) unitary operator in Fock space. Actually, this unitarity of the quantum dynamics leads us to identify as explicitly time dependent some very specific contributions of the Dirac field. In doing that, we essentially characterize the part of the dynamics governed by the Dirac equation that is unitarily implementable. The uniqueness of the Fock vacuum is attained then once a physically motivated convention for the concepts of particles and antiparticles is fixed. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
11. Three paths toward the quantum angle operator.
- Author
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Gazeau, Jean Pierre and Szafraniec, Franciszek Hugon
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QUANTUM operators , *PHASE transitions , *OPERATOR theory , *INVERSIONS (Geometry) , *QUANTIZATION (Physics) - Abstract
We examine mathematical questions around angle (or phase) operator associated with a number operator through a short list of basic requirements. We implement three methods of construction of quantum angle. The first one is based on operator theory and parallels the definition of angle for the upper half-circle through its cosine and completed by a sign inversion. The two other methods are integral quantization generalizing in a certain sense the Berezin–Klauder approaches. One method pertains to Weyl–Heisenberg integral quantization of the plane viewed as the phase space of the motion on the line. It depends on a family of “weight” functions on the plane. The third method rests upon coherent state quantization of the cylinder viewed as the phase space of the motion on the circle. The construction of these coherent states depends on a family of probability distributions on the line. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
12. Particle on a torus knot: Constrained dynamics and semi-classical quantization in a magnetic field.
- Author
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Das, Praloy, Pramanik, Souvik, and Ghosh, Subir
- Subjects
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TORUS knots , *SEMI-classical model (Atomic physics) , *QUANTIZATION (Physics) , *MAGNETIC fields , *CONSTRAINTS (Physics) , *FLUCTUATIONS (Physics) - Abstract
Kinematics and dynamics of a particle moving on a torus knot poses an interesting problem as a constrained system. In the first part of the paper we have derived the modified symplectic structure or Dirac brackets of the above model in Dirac’s Hamiltonian framework, both in toroidal and Cartesian coordinate systems. This algebra has been used to study the dynamics, in particular small fluctuations in motion around a specific torus. The spatial symmetries of the system have also been studied. In the second part of the paper we have considered the quantum theory of a charge moving in a torus knot in the presence of a uniform magnetic field along the axis of the torus in a semiclassical quantization framework. We exploit the Einstein–Brillouin–Keller (EBK) scheme of quantization that is appropriate for multidimensional systems. Embedding of the knot on a specific torus is inherently two dimensional that gives rise to two quantization conditions. This shows that although the system, after imposing the knot condition reduces to a one dimensional system, even then it has manifested non-planar features which shows up again in the study of fractional angular momentum. Finally we compare the results obtained from EBK (multi-dimensional) and Bohr–Sommerfeld (single dimensional) schemes. The energy levels and fractional spin depend on the torus knot parameters that specifies its non-planar features. Interestingly, we show that there can be non-planar corrections to the planar anyon-like fractional spin. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
13. Faddeev–Jackiw quantization of four dimensional BF theory.
- Author
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Escalante, Alberto and Sánchez, Prihel Cavildo
- Subjects
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FADDEEVA function , *QUANTIZATION (Physics) , *SYMPLECTIC groups , *GENERALIZATION , *DIRAC equation - Abstract
The symplectic analysis of a four dimensional B F theory in the context of the Faddeev–Jackiw symplectic approach is performed. It is shown that this method is more economical than Dirac’s formalism. In particular, the complete set of Faddeev–Jackiw constraints and the generalized Faddeev–Jackiw brackets are reported. In addition, we show that the generalized Faddeev–Jackiw brackets and the Dirac ones coincide to each other. Finally, the similarities and advantages between Faddeev–Jackiw method and Dirac’s formalism are briefly discussed. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
14. Exact quantisation of the relativistic Hopfield model.
- Author
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Belgiorno, F., Cacciatori, S.L., Dalla Piazza, F., and Doronzo, M.
- Subjects
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QUANTIZATION (Physics) , *RELATIVISTIC quantum theory , *HOPFIELD networks , *DIELECTRIC materials , *ELECTROMAGNETIC fields , *DIPOLE moments - Abstract
We investigate the quantisation in the Heisenberg representation of a relativistically covariant version of the Hopfield model for dielectric media, which entails the interaction of the quantum electromagnetic field with the matter dipole fields, represented by a mesoscopic polarisation field. A full quantisation of the model is provided in a covariant gauge, with the aim of maintaining explicit relativistic covariance. Breaking of the Lorentz invariance due to the intrinsic presence in the model of a preferred reference frame is also taken into account. Relativistic covariance forces us to deal with the unphysical (scalar and longitudinal) components of the fields, furthermore it introduces, in a more tricky form, the well-known dipole ghost of standard QED in a covariant gauge. In order to correctly dispose of this contribution, we implement a generalised Lautrup trick. Furthermore, causality and the relation of the model with the Wightman axioms are also discussed. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
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15. Separable quantizations of Stäckel systems.
- Author
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Błaszak, Maciej, Marciniak, Krzysztof, and Domański, Ziemowit
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SEPARABLE algebras , *HAMILTONIAN systems , *QUANTIZATION (Physics) , *POISSON distribution , *QUADRATIC equations - Abstract
In this article we prove that many Hamiltonian systems that cannot be separably quantized in the classical approach of Robertson and Eisenhart can be separably quantized if we extend the class of admissible quantizations through a suitable choice of Riemann space adapted to the Poisson geometry of the system. Actually, in this article we prove that for every quadratic in momenta Stäckel system (defined on 2 n dimensional Poisson manifold) for which Stäckel matrix consists of monomials in position coordinates there exist infinitely many quantizations–parametrized by n arbitrary functions–that turn this system into a quantum separable Stäckel system. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
16. Constraints on operator ordering from third quantization.
- Author
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Ohkuwa, Yoshiaki, Faizal, Mir, and Ezawa, Yasuo
- Subjects
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CONSTRAINTS (Physics) , *QUANTIZATION (Physics) , *QUANTUM fluctuations , *METAPHYSICAL cosmology , *PHYSICS research - Abstract
In this paper, we analyse the Wheeler–DeWitt equation in the third quantized formalism. We will demonstrate that for certain operator ordering, the early stages of the universe are dominated by quantum fluctuations, and the universe becomes classical at later stages during the cosmic expansion. This is physically expected, if the universe is formed from quantum fluctuations in the third quantized formalism. So, we will argue that this physical requirement can be used to constrain the form of the operator ordering chosen. We will explicitly demonstrate this to be the case for two different cosmological models. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
17. Quantum particle confined to a thin-layer volume: Non-uniform convergence toward the curved surface.
- Author
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Wang, Yong-Long and Zong, Hong-Shi
- Subjects
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QUANTUM mechanics , *STOCHASTIC convergence , *CURVED surfaces , *QUANTIZATION (Physics) - Abstract
We clearly refine the fundamental framework of the thin-layer quantization procedure, and further develop the procedure by taking the proper terms of degree one in q 3 ( q 3 denotes the curvilinear coordinate variable perpendicular to curved surface) back into the surface quantum equation. The well-known geometric potential and kinetic term are modified by the surface thickness. Applying the developed formalism to a toroidal system obtains the modification for the kinetic term and the modified geometric potential including the influence of the surface thickness. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
18. Particle detection and non-detection in a quantum time of arrival measurement.
- Author
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Sombillo, Denny Lane B. and Galapon, Eric A.
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PARTICLE detectors , *QUANTUM mechanics , *SPATIOTEMPORAL processes , *WAVE functions , *PROBABILITY theory , *QUANTIZATION (Physics) - Abstract
The standard time-of-arrival distribution cannot reproduce both the temporal and the spatial profile of the modulus squared of the time-evolved wave function for an arbitrary initial state. In particular, the time-of-arrival distribution gives a non-vanishing probability even if the wave function is zero at a given point for all values of time. This poses a problem in the standard formulation of quantum mechanics where one quantizes a classical observable and uses its spectral resolution to calculate the corresponding distribution. In this work, we show that the modulus squared of the time-evolved wave function is in fact contained in one of the degenerate eigenfunctions of the quantized time-of-arrival operator. This generalizes our understanding of quantum arrival phenomenon where particle detection is not a necessary requirement, thereby providing a direct link between time-of-arrival quantization and the outcomes of the two-slit experiment. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
19. Aharonov–Anandan quantum phases and Landau quantization associated with a magnetic quadrupole moment.
- Author
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Fonseca, I.C. and Bakke, K.
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QUANTUM theory , *QUANTIZATION (Physics) , *QUADRUPOLE moments , *MAGNETIC quantum number , *WAVE functions - Abstract
The arising of geometric quantum phases in the wave function of a moving particle possessing a magnetic quadrupole moment is investigated. It is shown that an Aharonov–Anandan quantum phase (Aharonov and Anandan, 1987) can be obtained in the quantum dynamics of a moving particle with a magnetic quadrupole moment. In particular, it is obtained as an analogue of the scalar Aharonov–Bohm effect for a neutral particle (Anandan, 1989). Besides, by confining the quantum particle to a hard-wall confining potential, the dependence of the energy levels on the geometric quantum phase is discussed and, as a consequence, persistent currents can arise from this dependence. Finally, an analogue of the Landau quantization is discussed. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
20. Multiport impedance quantization.
- Author
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Solgun, Firat and DiVincenzo, David P.
- Subjects
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ELECTRIC impedance , *QUANTIZATION (Physics) , *SUPERCONDUCTORS , *QUANTUM electrodynamics , *JOSEPHSON junctions - Abstract
With the increase of complexity and coherence of superconducting systems made using the principles of circuit quantum electrodynamics, more accurate methods are needed for the characterization, analysis and optimization of these quantum processors. Here we introduce a new method of modeling that can be applied to superconducting structures involving multiple Josephson junctions, high- Q superconducting cavities, external ports, and voltage sources. Our technique, an extension of our previous work on single-port structures (Solgun, 2014), permits the derivation of system Hamiltonians that are capable of representing every feature of the physical system over a wide frequency band and the computation of T 1 times for qubits. We begin with a “black box” model of the linear and passive part of the system. Its response is given by its multiport impedance function Z s i m ( ω ) , which can be obtained using a finite-element electromagnetics simulator. The ports of this black box are defined by the terminal pairs of Josephson junctions, voltage sources, and 50 Ω connectors to high-frequency lines. We fit Z s i m ( ω ) to a positive-real (PR) multiport impedance matrix Z ( s ) , a function of the complex Laplace variable s . We then use state-space techniques to synthesize a finite electric circuit admitting exactly the same impedance Z ( s ) across its ports; the PR property ensures the existence of this finite physical circuit. We compare the performance of state-space algorithms to classical frequency domain methods, justifying their superiority in numerical stability. The Hamiltonian of the multiport model circuit is obtained by using existing lumped element circuit quantization formalisms (Burkard et al., 2004; Burkard, 2005). Due to the presence of ideal transformers in the model circuit, these quantization methods must be extended, requiring the introduction of an extension of the Kirchhoff voltage and current laws. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
21. Faddeev–Jackiw quantization of an Abelian and non-Abelian exotic action for gravity in three dimensions.
- Author
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Escalante, Alberto and Manuel-Cabrera, J.
- Subjects
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QUANTIZATION (Physics) , *ABELIAN equations , *GRAVITY , *GAUGE invariance , *REGRESSION analysis - Abstract
A detailed Faddeev–Jackiw quantization of an Abelian and non-Abelian exotic action for gravity in three dimensions is performed. We obtain for the theories under study the constraints, the gauge transformations, the generalized Faddeev–Jackiw brackets and we perform the counting of physical degrees of freedom. In addition, we compare our results with those found in the literature where the canonical analysis is developed, in particular, we show that both the generalized Faddeev–Jackiw brackets and Dirac’s brackets coincide to each other. Finally we discuss some remarks and prospects. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
22. Incorporation of generalized uncertainty principle into Lifshitz field theories.
- Author
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Faizal, Mir and Majumder, Barun
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HEISENBERG uncertainty principle , *LIFSHITZ point (Physics) , *BOSONS , *FERMIONS , *STOCHASTIC processes , *QUANTIZATION (Physics) - Abstract
In this paper, we will incorporate the generalized uncertainty principle into field theories with Lifshitz scaling. We will first construct both bosonic and fermionic theories with Lifshitz scaling based on generalized uncertainty principle. After that we will incorporate the generalized uncertainty principle into a non-abelian gauge theory with Lifshitz scaling. We will observe that even though the action for this theory is non-local, it is invariant under local gauge transformations. We will also perform the stochastic quantization of this Lifshitz fermionic theory based generalized uncertainty principle. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
23. Attached open strings on a [formula omitted]-brane in the backgrounds of the pp-wave and linear dilation.
- Author
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Kamani, Davoud
- Subjects
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STRING theory , *BRANES , *DILATON , *NUMERICAL solutions to equations of motion , *QUANTIZATION (Physics) , *SPACETIME , *P-waves (Seismology) - Abstract
Open strings on a D p -brane in the pp-wave spacetime, accompanied by a linear dilaton background, will be studied. Various properties of this system such as solvability of equations of motion and quantization will be investigated. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
24. Study of the all orders multiplicative renormalizability of a local confining quark action in the Landau gauge.
- Author
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Capri, M.A.L., Fiorentini, D., and Sorella, S.P.
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FADDEEVA function , *QUANTIZATION (Physics) , *COUPLING constants , *LATTICE theory , *COMPUTER simulation - Abstract
The inverse of the Faddeev–Popov operator plays a pivotal role within the Gribov–Zwanziger approach to the quantization of Euclidean Yang–Mills theories in Landau gauge. Following a recent proposal (Capri et al., 2014), we show that the inverse of the Faddeev–Popov operator can be consistently coupled to quark fields. Such a coupling gives rise to a local action while reproducing the behaviour of the quark propagator observed in lattice numerical simulations in the non-perturbative infrared region. By using the algebraic renormalization framework, we prove that the aforementioned local action is multiplicatively renormalizable to all orders. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
25. Restricted phase-space approximation in real-time stochastic quantization.
- Author
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Anzaki, Ryoji, Fukushima, Kenji, Hidaka, Yoshimasa, and Oka, Takashi
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QUANTIZATION (Physics) , *QUANTUM theory , *LIGHT quantization , *QUANTIZATION methods (Quantum mechanics) , *SOUND quantization - Abstract
We perform and extend real-time numerical simulation of a low-dimensional scalar field theory or a quantum mechanical system using stochastic quantization. After a brief review of the quantization method and the complex Langevin dynamics, we calculate the propagator and make a comparison with analytical results. This is a first step toward general applications, and we focus only on the vacuum properties of the theory; this enables us to handle the boundary condition with the i ϵ prescription in frequency space. While we can control stability of the numerical simulation for any coupling strength, our results turn out to flow into an unphysical fixed-point, which is qualitatively understood from the corresponding Fokker–Planck equation. We propose a simple truncation scheme, “restricted phase-space approximation”, to avoid the unphysical fixed-point. With this method, we obtain stable results at reasonably good accuracy. Finally we give a short discussion on the closed-time path formalism and demonstrate the direct computation of the vacuum expectation value not with the i ϵ prescription but from an explicit construction of the Feynman kernel. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
26. An exactly solvable deformation of the Coulomb problem associated with the Taub–NUT metric.
- Author
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Ballesteros, Ángel, Enciso, Alberto, Herranz, Francisco J., Ragnisco, Orlando, and Riglioni, Danilo
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QUANTIZATION (Physics) , *COULOMB functions , *SOLVABLE groups , *DEFORMATIONS (Mechanics) , *STATISTICAL association , *HAMILTONIAN systems - Abstract
In this paper we quantize the N -dimensional classical Hamiltonian system H = | q | 2 ( η + | q | ) p 2 − k η + | q | , that can be regarded as a deformation of the Coulomb problem with coupling constant k , that it is smoothly recovered in the limit η → 0 . Moreover, the kinetic energy term in H is just the one corresponding to an N -dimensional Taub–NUT space, a fact that makes this system relevant from a geometric viewpoint. Since the Hamiltonian H is known to be maximally superintegrable, we propose a quantization prescription that preserves such superintegrability in the quantum mechanical setting. We show that, to this end, one must choose as the kinetic part of the Hamiltonian the conformal Laplacian of the underlying Riemannian manifold, which combines the usual Laplace–Beltrami operator on the Taub–NUT manifold and a multiple of its scalar curvature. As a consequence, we obtain a novel exactly solvable deformation of the quantum Coulomb problem, whose spectrum is computed in closed form for positive values of η and k , and showing that the well-known maximal degeneracy of the flat system is preserved in the deformed case. Several interesting algebraic and physical features of this new exactly solvable quantum system are analyzed, and the quantization problem for negative values of η and/or k is also sketched. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
27. From the Weyl quantization of a particle on the circle to number–phase Wigner functions.
- Author
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Przanowski, Maciej, Brzykcy, Przemysław, and Tosiek, Jaromir
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QUANTIZATION (Physics) , *QUANTUM optics , *WEYL space , *PARTICLES (Nuclear physics) , *WIGNER distribution , *GENERALIZATION - Abstract
A generalized Weyl quantization formalism for a particle on the circle is shown to supply an effective method for defining the number–phase Wigner function in quantum optics. A Wigner function for the state ϱ ˆ and the kernel K for a particle on the circle is defined and its properties are analysed. Then it is shown how this Wigner function can be easily modified to give the number–phase Wigner function in quantum optics. Some examples of such number–phase Wigner functions are considered. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
28. En route to Background Independence: Broken split-symmetry, and how to restore it with bi-metric average actions.
- Author
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Becker, D. and Reuter, M.
- Subjects
- *
QUANTUM gravity , *SYMMETRY (Physics) , *ASYMPTOTIC expansions , *QUANTIZATION (Physics) , *RENORMALIZATION group - Abstract
The most momentous requirement a quantum theory of gravity must satisfy is Background Independence, necessitating in particular an ab initio derivation of the arena all non-gravitational physics takes place in, namely spacetime. Using the background field technique, this requirement translates into the condition of an unbroken split-symmetry connecting the (quantized) metric fluctuations to the (classical) background metric. If the regularization scheme used violates split-symmetry during the quantization process it is mandatory to restore it in the end at the level of observable physics. In this paper we present a detailed investigation of split-symmetry breaking and restoration within the Effective Average Action (EAA) approach to Quantum Einstein Gravity (QEG) with a special emphasis on the Asymptotic Safety conjecture. In particular we demonstrate for the first time in a non-trivial setting that the two key requirements of Background Independence and Asymptotic Safety can be satisfied simultaneously. Carefully disentangling fluctuation and background fields, we employ a ‘bi-metric’ ansatz for the EAA and project the flow generated by its functional renormalization group equation on a truncated theory space spanned by two separate Einstein–Hilbert actions for the dynamical and the background metric, respectively. A new powerful method is used to derive the corresponding renormalization group (RG) equations for the Newton- and cosmological constant, both in the dynamical and the background sector. We classify and analyze their solutions in detail, determine their fixed point structure, and identify an attractor mechanism which turns out instrumental in the split-symmetry restoration. We show that there exists a subset of RG trajectories which are both asymptotically safe and split-symmetry restoring: In the ultraviolet they emanate from a non-Gaussian fixed point, and in the infrared they loose all symmetry violating contributions inflicted on them by the non-invariant functional RG equation. As an application, we compute the scale dependent spectral dimension which governs the fractal properties of the effective QEG spacetimes at the bi-metric level. Earlier tests of the Asymptotic Safety conjecture almost exclusively employed ‘single-metric truncations’ which are blind towards the difference between quantum and background fields. We explore in detail under which conditions they can be reliable, and we discuss how the single-metric based picture of Asymptotic Safety needs to be revised in the light of the new results. We shall conclude that the next generation of truncations for quantitatively precise predictions (of critical exponents, for instance) is bound to be of the bi-metric type. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
29. Unimodular theory: A little pedagogical vision.
- Author
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Fernández Cristóbal, Jose M a
- Subjects
- *
GRAVITY , *FIELD theory (Physics) , *QUANTIZATION (Physics) , *COSMOLOGICAL constant , *DIFFEOMORPHISMS - Abstract
Under the generic designation of unimodular theory, two theoretical models of gravity are considered: the unimodular gravity and the TDiff theory. Our approach is primarily pedagogical. We aim to describe these models both from a geometric and a field-theoretical point of view. In addition, we explore connections with the cosmological-constant problem and outline some applications. We do not discuss the application of this theory to the quantization of gravity. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
30. Fractional corresponding operator in quantum mechanics and applications: A uniform fractional Schrödinger equation in form and fractional quantization methods.
- Author
-
Zhang, Xiao, Wei, Chaozhen, Liu, Yingming, and Luo, Maokang
- Subjects
- *
FRACTIONAL quantum mechanics , *OPERATOR theory , *SCHRODINGER equation , *QUANTIZATION (Physics) , *DIRAC function , *FRACTIONAL calculus - Abstract
In this paper we use Dirac function to construct a fractional operator called fractional corresponding operator, which is the general form of momentum corresponding operator. Then we give a judging theorem for this operator and with this judging theorem we prove that R–L, G–L, Caputo, Riesz fractional derivative operator and fractional derivative operator based on generalized functions, which are the most popular ones, coincide with the fractional corresponding operator. As a typical application, we use the fractional corresponding operator to construct a new fractional quantization scheme and then derive a uniform fractional Schrödinger equation in form. Additionally, we find that the five forms of fractional Schrödinger equation belong to the particular cases. As another main result of this paper, we use fractional corresponding operator to generalize fractional quantization scheme by using Lévy path integral and use it to derive the corresponding general form of fractional Schrödinger equation, which consequently proves that these two quantization schemes are equivalent. Meanwhile, relations between the theory in fractional quantum mechanics and that in classic quantum mechanics are also discussed. As a physical example, we consider a particle in an infinite potential well. We give its wave functions and energy spectrums in two ways and find that both results are the same. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
31. Landau quantization in the spinning cosmic string spacetime.
- Author
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Muniz, C.R., Bezerra, V.B., and Cunha, M.S.
- Subjects
- *
LANDAU damping , *QUANTIZATION (Physics) , *MAGNETIC fields , *SCHRODINGER equation , *TOPOLOGICAL defects (Physics) , *SPACETIME - Abstract
We analyze the quantum phenomenon arising from the interaction of a spinless charged particle with a rotating cosmic string, under the action of a static and uniform magnetic field parallel to the string. We calculate the energy levels of the particle in the non-relativistic approach, showing how these energies depend on the parameters involved in the problem. In order to do this, we solve the time independent Schrödinger equation in the geometry of the spinning cosmic string, taking into account that the coupling between the rotation of the spacetime and the angular momentum of the particle is very weak, such that makes sense to apply the Schrödinger equation in a curved background whose metric has an off diagonal term which involves time and space. It is also assumed that the particle orbits sufficiently far from the boundary of the region of closed timelike curves which exist around this topological defect. Finally, we find the Landau levels of the particle in the presence of a spinning cosmic string endowed with internal structure, i.e. , having a finite width and uniformly filled with both material and vacuum energies. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
32. First quantized electrodynamics.
- Author
-
Bennett, A.F.
- Subjects
- *
QUANTUM electrodynamics , *QUANTIZATION (Physics) , *BETHE-Salpeter equation , *MAGNETIC moments , *HYDROGEN , *SPECTRUM analysis , *DIRAC equation , *WAVE equation - Abstract
Abstract: The parametrized Dirac wave equation represents position and time as operators, and can be formulated for many particles. It thus provides, unlike field-theoretic Quantum Electrodynamics (QED), an elementary and unrestricted representation of electrons entangled in space or time. The parametrized formalism leads directly and without further conjecture to the Bethe–Salpeter equation for bound states. The formalism also yields the Uehling shift of the hydrogenic spectrum, the anomalous magnetic moment of the electron to leading order in the fine structure constant, the Lamb shift and the axial anomaly of QED. [Copyright &y& Elsevier]
- Published
- 2014
- Full Text
- View/download PDF
33. Integral quantizations with two basic examples.
- Author
-
Bergeron, H. and Gazeau, J.P.
- Subjects
- *
QUANTIZATION (Physics) , *QUANTUM theory , *SPECTRUM analysis , *COHERENT states , *HEISENBERG model , *OPERATOR theory , *PHASE space - Abstract
Abstract: The paper concerns integral quantization, a procedure based on operator-valued measure and resolution of the identity. We insist on covariance properties in the important case where group representation theory is involved. We also insist on the inherent probabilistic aspects of this classical–quantum map. The approach includes and generalizes coherent state quantization. Two applications based on group representation are carried out. The first one concerns the Weyl–Heisenberg group and the euclidean plane viewed as the corresponding phase space. We show that a world of quantizations exist, which yield the canonical commutation rule and the usual quantum spectrum of the harmonic oscillator. The second one concerns the affine group of the real line and gives rise to an interesting regularization of the dilation origin in the half-plane viewed as the corresponding phase space. [Copyright &y& Elsevier]
- Published
- 2014
- Full Text
- View/download PDF
34. Affine group formulation of the Standard Model coupled to gravity.
- Author
-
Chou, Ching-Yi, Ita, Eyo, and Soo, Chopin
- Subjects
- *
STANDARD model (Nuclear physics) , *GRAVITY , *HAMILTONIAN systems , *COSMOLOGICAL constant , *FERMIONS , *QUANTIZATION (Physics) , *CHERN-Simons gauge theory - Abstract
Abstract: In this work we apply the affine group formalism for four dimensional gravity of Lorentzian signature, which is based on Klauder’s affine algebraic program, to the formulation of the Hamiltonian constraint of the interaction of matter and all forces, including gravity with non-vanishing cosmological constant , as an affine Lie algebra. We use the hermitian action of fermions coupled to gravitation and Yang–Mills theory to find the density weight one fermionic super-Hamiltonian constraint. This term, combined with the Yang–Mills and Higgs energy densities, are composed with York’s integrated time functional. The result, when combined with the imaginary part of the Chern–Simons functional , forms the affine commutation relation with the volume element . Affine algebraic quantization of gravitation and matter on equal footing implies a fundamental uncertainty relation which is predicated upon a non-vanishing cosmological constant. [Copyright &y& Elsevier]
- Published
- 2014
- Full Text
- View/download PDF
35. Canonical quantization theory of general singular QED system of Fermi field interaction with generally decomposed gauge potential.
- Author
-
Zhang, Zhen-Lu and Huang, Yong-Chang
- Subjects
- *
QUANTUM electrodynamics , *QUANTIZATION (Physics) , *GAUGE field theory , *FERMIONS , *PHONONS , *NUCLEAR spin - Abstract
Abstract: Quantization theory gives rise to transverse phonons for the traditional Coulomb gauge condition and to scalar and longitudinal photons for the Lorentz gauge condition. We describe a new approach to quantize the general singular QED system by decomposing a general gauge potential into two orthogonal components in general field theory, which preserves scalar and longitudinal photons. Using these two orthogonal components, we obtain an expansion of the gauge-invariant Lagrangian density, from which we deduce the two orthogonal canonical momenta conjugate to the two components of the gauge potential. We then obtain the canonical Hamiltonian in the phase space and deduce the inherent constraints. In terms of the naturally deduced gauge condition, the quantization results are exactly consistent with those in the traditional Coulomb gauge condition and superior to those in the Lorentz gauge condition. Moreover, we find that all the nonvanishing quantum commutators are permanently gauge-invariant. A system can only be measured in physical experiments when it is gauge-invariant. The vanishing longitudinal vector potential means that the gauge invariance of the general QED system cannot be retained. This is similar to the nucleon spin crisis dilemma, which is an example of a physical quantity that cannot be exactly measured experimentally. However, the theory here solves this dilemma by keeping the gauge invariance of the general QED system. [Copyright &y& Elsevier]
- Published
- 2014
- Full Text
- View/download PDF
36. Resurgent deformation quantisation.
- Author
-
Garay, Mauricio, de Goursac, Axel, and van Straten, Duco
- Subjects
- *
DEFORMATIONS (Mechanics) , *QUANTIZATION (Physics) , *HEISENBERG model , *CONTINUATION methods , *QUANTUM efficiency , *MATHEMATICAL analysis - Abstract
Abstract: We construct a version of the complex Heisenberg algebra based on the idea of endless analytic continuation. The algebra would be large enough to capture quantum effects that escape ordinary formal deformation quantisation. [Copyright &y& Elsevier]
- Published
- 2014
- Full Text
- View/download PDF
37. Can Dirac quantization of constrained systems be fulfilled within the intrinsic geometry?
- Author
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Xun, D.M. and Liu, Q.H.
- Subjects
- *
QUANTIZATION (Physics) , *PROBLEM solving , *HAMILTONIAN systems , *QUANTUM mechanics , *CARTESIAN coordinates , *CURVED surfaces , *SCHRODINGER equation - Abstract
For particles constrained on a curved surface, how to perform quantization within Dirac’s canonical quantization scheme is a long-standing problem. On one hand, Dirac stressed that the Cartesian coordinate system has fundamental importance in passing from the classical Hamiltonian to its quantum mechanical form while preserving the classical algebraic structure between positions, momenta and Hamiltonian to the extent possible. On the other, on the curved surface, we have no exact Cartesian coordinate system within intrinsic geometry. These two facts imply that the three-dimensional Euclidean space in which the curved surface is embedded must be invoked otherwise no proper canonical quantization is attainable. In this paper, we take a minimum surface, helicoid, on which the motion is constrained, to explore whether the intrinsic geometry offers a proper framework in which the quantum theory can be established in a self-consistent way. Results show that not only an inconsistency within Dirac theory occurs, but also an incompatibility with Schrödinger theory happens. In contrast, in three-dimensional Euclidean space, the Dirac quantization turns out to be satisfactory all around, and the resultant geometric momentum and potential are then in agreement with those given by the Schrödinger theory. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
38. Casimir effect for a scalar field via Krein quantization.
- Author
-
Pejhan, H., Tanhayi, M.R., and Takook, M.V.
- Subjects
- *
CASIMIR effect , *SCALAR field theory , *QUANTIZATION (Physics) , *DIRICHLET problem , *BOUNDARY value problems , *MATHEMATICAL models - Abstract
Abstract: In this work, we present a rather simple method to study the Casimir effect on a spherical shell for a massless scalar field with Dirichlet boundary condition by applying the indefinite metric field (Krein) quantization technique. In this technique, the field operators are constructed from both negative and positive norm states. Having understood that negative norm states are un-physical, they are only used as a mathematical tool for renormalizing the theory and then one can get rid of them by imposing some proper physical conditions. [Copyright &y& Elsevier]
- Published
- 2014
- Full Text
- View/download PDF
39. Zero modes in the light-front coupled-cluster method.
- Author
-
Chabysheva, Sophia S. and Hiller, John R.
- Subjects
- *
COUPLED-cluster theory , *HAMILTONIAN systems , *EIGENVALUES , *PROBLEM solving , *QUANTIZATION (Physics) , *FIELD theory (Physics) - Abstract
Abstract: The light-front coupled-cluster (LFCC) method is a technique for solving Hamiltonian eigenvalue problems in light-front-quantized field theories. Its primary purpose is to provide a systematic sequence of solvable approximations to the original eigenvalue problem without the truncation of Fock space. Here we discuss the incorporation of zero modes, modes of zero longitudinal momentum, into the formalism of the method. Without zero modes, the light-front vacuum is trivial, and the vacuum expectation value of the field is always zero. The LFCC method with zero modes provides for vacuum structure, in the form of a generalized coherent state of zero modes, as is illustrated here in two-dimensional model field theories. [Copyright &y& Elsevier]
- Published
- 2014
- Full Text
- View/download PDF
40. On solvability and integrability of the Rabi model.
- Author
-
Moroz, Alexander
- Subjects
- *
HILBERT space , *ANALYTIC functions , *ORTHOGONAL polynomials , *EIGENVALUE equations , *EIGENFUNCTIONS , *QUANTIZATION (Physics) - Abstract
Abstract: The quasi-exactly solvable Rabi model is investigated within the framework of the Bargmann Hilbert space of analytic functions . On applying the theory of orthogonal polynomials, the eigenvalue equation and eigenfunctions are shown to be determined in terms of three systems of monic orthogonal polynomials. The formal Schweber quantization criterion for an energy variable , originally expressed in terms of infinite continued fractions, can be recast in terms of a meromorphic function in the complex plane with real simple poles and positive residues . The zeros of on the real axis determine the spectrum of the Rabi model. One obtains at once that, on the real axis, (i) monotonically decreases from to between any two of its subsequent poles and , (ii) there is exactly one zero of for , and (iii) the spectrum corresponding to the zeros of does not have any accumulation point. Additionally, one can provide a much simpler proof that the spectrum in each parity eigenspace is necessarily nondegenerate. Thereby the calculation of spectra is greatly facilitated. Our results allow us to critically examine recent claims regarding solvability and integrability of the Rabi model. [Copyright &y& Elsevier]
- Published
- 2013
- Full Text
- View/download PDF
41. Quantizations from reproducing kernel spaces
- Author
-
Twareque Ali, S., Bagarello, F., and Pierre Gazeau, Jean
- Subjects
- *
QUANTIZATION (Physics) , *KERNEL functions , *HILBERT space , *HERMITE polynomials , *PARAMETER estimation , *EQUIVALENCE classes (Set theory) - Abstract
Abstract: The purpose of this work is to explore the existence and properties of reproducing kernel Hilbert subspaces of based on subsets of complex Hermite polynomials. The resulting coherent states (CS) form a family depending on a nonnegative parameter . We examine some interesting issues, mainly related to CS quantization, like the existence of the usual harmonic oscillator spectrum despite the absence of canonical commutation rules. The question of mathematical and physical equivalences between the -dependent quantizations is also considered. [Copyright &y& Elsevier]
- Published
- 2013
- Full Text
- View/download PDF
42. Pisot -coherent states quantization of the harmonic oscillator
- Author
-
Gazeau, J.P. and del Olmo, M.A.
- Subjects
- *
QUANTIZATION (Physics) , *HARMONIC oscillators , *COHERENT states , *SET theory , *FIBONACCI sequence , *PHASE space - Abstract
Abstract: We revisit the quantized version of the harmonic oscillator obtained through a -dependent family of coherent states. For each , , these normalized states form an overcomplete set that resolves the unity with respect to an explicit measure. We restrict our study to the case in which is a quadratic unit Pisot number, since then the -deformed integers form Fibonacci-like sequences of integers. We then examine the main characteristics of the corresponding quantum oscillator: localization in the configuration and in the phase spaces, angle operator, probability distributions and related statistical features, time evolution and semi-classical phase space trajectories. [Copyright &y& Elsevier]
- Published
- 2013
- Full Text
- View/download PDF
43. The coordinate coherent states approach revisited
- Author
-
Miao, Yan-Gang and Zhang, Shao-Jun
- Subjects
- *
COHERENT states , *QUANTIZATION (Physics) , *QUANTUM field theory , *OPERATOR theory , *DIRAC function , *TEMPERATURE - Abstract
Abstract: We revisit the coordinate coherent states approach through two different quantization procedures in the quantum field theory on the noncommutative Minkowski plane. The first procedure, which is based on the normal commutation relation between an annihilation and creation operators, deduces that a point mass can be described by a Gaussian function instead of the usual Dirac delta function. However, we argue this specific quantization by adopting the canonical one (based on the canonical commutation relation between a field and its conjugate momentum) and show that a point mass should still be described by the Dirac delta function, which implies that the concept of point particles is still valid when we deal with the noncommutativity by following the coordinate coherent states approach. In order to investigate the dependence on quantization procedures, we apply the two quantization procedures to the Unruh effect and Hawking radiation and find that they give rise to significantly different results. Under the first quantization procedure, the Unruh temperature and Unruh spectrum are not deformed by noncommutativity, but the Hawking temperature is deformed by noncommutativity while the radiation specturm is untack. However, under the second quantization procedure, the Unruh temperature and Hawking temperature are untack but the both spectra are modified by an effective greybody (deformed) factor. [Copyright &y& Elsevier]
- Published
- 2013
- Full Text
- View/download PDF
44. Krein regularization of QED
- Author
-
Forghan, B., Takook, M.V., and Zarei, A.
- Subjects
- *
MATHEMATICAL regularization , *QUANTUM electrodynamics , *FLUCTUATIONS (Physics) , *KREIN spaces , *PHOTONS , *QUANTIZATION (Physics) - Abstract
Abstract: In this paper, the electron self-energy, photon self-energy and vertex functions are explicitly calculated in Krein space quantization including quantum metric fluctuation. The results are automatically regularized or finite. The magnetic anomaly and Lamb shift are also calculated in the one loop approximation in this method. Finally, the obtained results are compared to conventional QED results. [Copyright &y& Elsevier]
- Published
- 2012
- Full Text
- View/download PDF
45. Classical geometry to quantum behavior correspondence in a virtual extra dimension
- Author
-
Dolce, Donatello
- Subjects
- *
GEOMETRY , *QUANTUM theory , *DIMENSION theory (Topology) , *LORENTZ force , *SPACETIME , *QUANTIZATION (Physics) , *BOUNDARY value problems - Abstract
Abstract: In the Lorentz invariant formalism of compact space–time dimensions the assumption of periodic boundary conditions represents a consistent semi-classical quantization condition for relativistic fields. In Dolce (2011) we have shown, for instance, that the ordinary Feynman path integral is obtained from the interference between the classical paths with different winding numbers associated with the cyclic dynamics of the field solutions. By means of the boundary conditions, the kinematical information of interactions can be encoded on the relativistic geometrodynamics of the boundary, see Dolce (2012) . Furthermore, such a purely four-dimensional theory is manifestly dual to an extra-dimensional field theory. The resulting correspondence between extra-dimensional geometrodynamics and ordinary quantum behavior can be interpreted in terms of AdS/CFT correspondence. By applying this approach to a simple Quark–Gluon–Plasma freeze-out model we obtain fundamental analogies with basic aspects of AdS/QCD phenomenology. [Copyright &y& Elsevier]
- Published
- 2012
- Full Text
- View/download PDF
46. The dynamical-quantization approach to open quantum systems
- Author
-
Bolivar, A.O.
- Subjects
- *
QUANTIZATION (Physics) , *QUANTUM theory , *BROWNIAN motion , *FOKKER-Planck equation , *TEMPERATURE effect , *GRAVITATIONAL fields - Abstract
Abstract: The dynamical-quantization approach to open quantum systems does consist in quantizing the Brownian motion starting directly from its stochastic dynamics under the framework of both Langevin and Fokker–Planck equations, without alluding to any model Hamiltonian. On the ground of this non-Hamiltonian quantization method, we can derive a non-Markovian Caldeira–Leggett quantum master equation as well as a non-Markovian quantum Smoluchowski equation. The former is solved for the case of a quantum Brownian particle in a gravitational field whilst the latter for a harmonic oscillator. In both physical situations, we come up with the existence of a non-equilibrium thermal quantum force and investigate its classical limit at high temperatures as well as its quantum limit at zero temperature. Further, as a physical application of our quantum Smoluchowski equation, we take up the tunneling phenomenon of a non-inertial quantum Brownian particle over a potential barrier. Lastly, we wish to point out, corroborating conclusions reached in our previous paper [A. O. Bolivar, Ann. Phys. 326 (2011) 1354], that the theoretical predictions in the present article uphold the view that our non-Hamiltonian quantum mechanics is able to capture novel features inherent in quantum Brownian motion, thereby overcoming shortcomings underlying the Caldeira–Leggett Hamiltonian model. [Copyright &y& Elsevier]
- Published
- 2012
- Full Text
- View/download PDF
47. Phase space quantum mechanics
- Author
-
Błaszak, Maciej and Domański, Ziemowit
- Subjects
- *
PHASE space , *QUANTUM theory , *DEFORMATIONS (Mechanics) , *QUANTIZATION (Physics) , *HAMILTONIAN systems , *POISSON brackets - Abstract
Abstract: This paper develops an alternative formulation of quantum mechanics known as the phase space quantum mechanics or deformation quantization. It is shown that the quantization naturally arises as an appropriate deformation of the classical Hamiltonian mechanics. More precisely, the deformation of the point-wise product of observables to an appropriate noncommutative -product and the deformation of the Poisson bracket to an appropriate Lie bracket are the key elements in introducing the quantization of classical Hamiltonian systems. The formalism of the phase space quantum mechanics is presented in a very systematic way for the case of any smooth Hamiltonian function and for a very wide class of deformations. The considered class of deformations and the corresponding -products contains as a special case all deformations which can be found in the literature devoted to the subject of the phase space quantum mechanics. Fundamental properties of -products of observables, associated with the considered deformations are presented as well. Moreover, a space of states containing all admissible states is introduced, where the admissible states are appropriate pseudo-probability distributions defined on the phase space. It is proved that the space of states is endowed with a structure of a Hilbert algebra with respect to the -multiplication. The most important result of the paper shows that developed formalism is more fundamental than the axiomatic ordinary quantum mechanics which appears in the presented approach as the intrinsic element of the general formalism. The equivalence of two formulations of quantum mechanics is proved by observing that the Wigner–Moyal transform has all properties of the tensor product. This observation allows writing many previous results found in the literature in a transparent way, from which the equivalence of the two formulations of quantum mechanics follows naturally. In addition, examples of a free particle and a simple harmonic oscillator illustrating the formalism of the deformation quantization and its classical limit are given. [Copyright &y& Elsevier]
- Published
- 2012
- Full Text
- View/download PDF
48. A semiclassical description of relativistic spin without the use of Grassmann variables and the Dirac equation
- Author
-
Deriglazov, A.A.
- Subjects
- *
MATHEMATICAL variables , *DIRAC equation , *RELATIVISTIC particles , *NUCLEAR spin , *QUANTIZATION (Physics) , *MATHEMATICAL models - Abstract
Abstract: We propose a relativistic particle model without Grassmann variables which, being canonically quantized, leads to the Dirac equation. Both -matrices and the relativistic spin tensor are produced through the canonical quantization of the classical variables which parametrize the properly constructed relativistic spin surface. Although there is no mass–shell constraint in our model, our particle’s speed cannot exceed the speed of light. The classical dynamics of the model is in correspondence with the dynamics of mean values of the corresponding operators in the Dirac theory. In particular, the position variable experiences Zitterbewegung in noninteracting theory. The classical equations for the spin tensor are the same as those of the Barut–Zanghi model of a spinning particle. [Copyright &y& Elsevier]
- Published
- 2012
- Full Text
- View/download PDF
49. Landau quantization for an electric quadrupole moment of position-dependent mass quantum particles interacting with electromagnetic fields.
- Author
-
Algadhi, Zeinab and Mustafa, Omar
- Subjects
- *
QUADRUPOLE moments , *ELECTROMAGNETIC fields , *MAGNETIC fields , *ELECTRIC fields , *MAGNETIC particles , *LANDAU levels , *QUANTIZATION (Physics) - Abstract
Analogous to Landau quantization related to a neutral particle possessing an electric quadrupole moment, we generalize such a Landau quantization to include position-dependent mass (PDM) neutral particles. Using cylindrical coordinates, the exact solvability of PDM neutral particles with an electric quadrupole moment moving in electromagnetic fields is reported. The interaction between the electric quadrupole moment of a PDM neutral particle and a magnetic field in the absence of an electric field is analyzed for two different radial cylindrical PDM settings. Next, two particular cases of radial electric fields (E ⃗ = λ ρ ρ ̂ a n d E ⃗ = λ ρ 2 ρ ̂) are considered to investigate their influence on the Landau quantization (of this system using the same models of PDM settings). The exact eigenvalues and eigenfunctions for each case are analytically obtained. • Quantum mechanical systems with position-dependent mass (PDM). • The PDM-minimal-coupling and the PDM-momentum operator. • Position-dependent-mass charged particles in position-dependent magnetic fields. • The quantum mechanical effects on PDM neutral particles possessing an electric quadrupole moment. • Landau quantization for PDM neutral particles possessing an electric quadrupole moment interacting with external fields (electric and magnetic fields). [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
50. Corrigendum to “Constraints on operator ordering from third quantization” [Ann. Phys. 365 (2016) 54–65].
- Author
-
Ohkuwa, Yoshiaki, Faizal, Mir, and Ezawa, Yasuo
- Subjects
- *
QUANTIZATION (Physics) , *NUCLEAR forces (Physics) - Abstract
In our previous paper Ohkuwa et al. (2016) corrigendum was found in Eqs. (3.4) and (3.6) . However, conclusions of our previous paper are not changed. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
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