Reduced Order Podolsky Model

Thibes, Ronaldo

doi:10.1007/s13538-016-0475-7

Cited by 14 publications

(16 citation statements)

References 34 publications

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“…which agrees with Eq. (36). We therefore verity that the equivalence between the classical equations of motion in the Ostrogradsky and Reduction of order prescriptions, seen in Eqs.…”

Section: A Ostrogradsky Formalismsupporting

confidence: 65%

“…Although the (FJ) formalism does not implement major changes in the quantization process of a regular theory, in a singular theory there might be considerable simplifications when adopting the symplectic formalism instead of the usual (DB) algorithm. We apply the (FJ) method to discuss the quantization of the Podolsky electrodynamics [41] but, differently from what was done in [39], we start by writing the theory in the reduction of order formalism, by means of the introduction of an additional auxiliary field B µ , following [36]. We will show that this technique allows us to write the sympletic matrix in a block structure, thus clearly separating the Maxwell and Proca sectors.…”

Section: Hd Podolsky Theory In the (Fj) Formalismmentioning

confidence: 99%

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Reduction of order and Fadeev–Jackiw formalism in generalized electrodynamics

2019

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The aim of this work is to discuss some aspects of the reduction of order formalism in the context of the Fadeev-Jackiw symplectic formalism, both at the classical and the quantum level. We start by reviewing the symplectic analysis in a regular theory (a higher derivative massless scalar theory), both using the Ostrogradsky prescription and also by reducing the order of the Lagrangian with an auxiliary field, showing the equivalence of these two approaches. The interpretation of the degrees of freedom is discussed in some detail. Finally, we perform the similar analysis in a singular higher derivative gauge theory (the Podolsky electrodynamics), in the reduced order formalism: we claim that this approach have the advantage of clearly separating the symplectic structure of the model into a Maxwell and a Proca (ghost) sector, thus complementing the understanding of the degrees of freedom of the theory and simplifying calculations involving matrices.

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“…which agrees with Eq. (36). We therefore verity that the equivalence between the classical equations of motion in the Ostrogradsky and Reduction of order prescriptions, seen in Eqs.…”

Section: A Ostrogradsky Formalismsupporting

confidence: 65%

Section: Hd Podolsky Theory In the (Fj) Formalismmentioning

confidence: 99%

Reduction of order and Fadeev–Jackiw formalism in generalized electrodynamics

2019

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“…(25) for the scattering region. For this, we will use the technique of the Green function (Suzuki;Sales, 2003;Suzuki;Sales;Carrillo, 2013;Sales;Suzuki, 2013;Thibes, 2017). Thus, being the Green function for Eq.…”

Section: Schrödinger Integral Equationmentioning

confidence: 99%

Computational Model of the Fredholm Method Applied to Podolsky Quantum Wave Function / Modelo Computacional Do Método Fredholm Aplicado À Função Onda Quântica De Podolsky

Sales

Girotto

Soglia

2021

BJD

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In this paper we used the Fredholm method in Schrödinger's integral equation in the investigation of the scattering effect near the center of it between a stationary quantum wave function and an electrostatic potential. Two potentials are studied one Coulombian and the other Podolsky. The result shows the importance of the proposal of Podolsky to regularize the effect near the scattering center in the quantum wave function. Being that the coulombian potential presents with strong variation in the amplitude of the wave after the scattering. In the case of Podolsky's potential, this is corrected by adopting a constant that removes this strong variation.

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“…We have shown that for even values of N , the homogeneous equation ( 23) has only the trivial solution φ ≡ 0. Also the infinite-order homogeneous equation (26) does not have non-trivial solutions for φ.…”

Section: Conclusion and Final Remarksmentioning

confidence: 99%

“…Another interesting path for obtaining higher-derivative models can be seen in [25], where it is shown that nonlocality in space-time via the introduction of forward and back-ward fields can lead to higher-order derivatives with a particular example of a fourth-order generalization of the KG equation given. In this day and age, the study of higher-derivative theories continues to be an active lively field, still containing various chalenging problems and being the main subject of a significative number of works in the most recent literature [26,27,28,29,30,31,32,33,34]. Besides their own mathematical interest, the address of important issues and open questions in physics such as the quantization of gravity and its alternative modified theories, the construction of effective low energy field theories, the dark energy and matter problems and the possibility of Lorentz symmetry breaking at a fundamental level in cosmological models has granted higher-derivative models an important role in the current contemporary physics scenario [35,36,37,38,39].…”

Section: Introductionmentioning

confidence: 99%

Natural Higher-Derivatives Generalization for the Klein-Gordon Equation

Thibes

2020

Preprint

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We propose a natural family of higher-order partial differential equations generalizing the second-order Klein-Gordon equation. We characterize the associated model by means of a generalized action for a scalar field, containing higher-derivative terms. The limit obtained by considering arbitrarily higher-order powers of the d'Alembertian operator leading to a formal infinite-order partial differential equation is discussed. The general model is constructed using the exponential of the d'Alembertian differential operator. The canonical energymomentum tensor densities and field propagators are explicitly computed. We consider both homogeneous and non-homogeneous situations. The classical solutions are obtained for all cases.

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Reduced Order Podolsky Model

Cited by 14 publications

References 34 publications

Reduction of order and Fadeev–Jackiw formalism in generalized electrodynamics

Reduction of order and Fadeev–Jackiw formalism in generalized electrodynamics

Computational Model of the Fredholm Method Applied to Podolsky Quantum Wave Function / Modelo Computacional Do Método Fredholm Aplicado À Função Onda Quântica De Podolsky

Natural Higher-Derivatives Generalization for the Klein-Gordon Equation

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