Fractional formulation of Podolsky Lagrangian density

Lagrangians which depend on higher-order derivatives appear frequently in many areas of physics. In this paper, we reformulate Podolsky's Lagrangian in fractional form using left-right Riemann-Liouville fractional derivatives. The equations of motion are obtained using the fractional Euler Lagrange equation. In addition, the energy stress tensor and the Hamiltonian are obtained in fractional form from the Lagrangian density. The resulting equations are very similar to those found in classical field theory.

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Elements of Classical Field Theory

10.1093/oso/9780192844200.003.0003 ◽

2021 ◽

pp. 24-34

Author(s):

J. Iliopoulos ◽

T.N. Tomaras

Keyword(s):

Field Theory ◽

Degrees Of Freedom ◽

Equations Of Motion ◽

Classical Mechanics ◽

Classical Field Theory ◽

Classical Field ◽

Lagrange Equations ◽

Lie Group Of Transformations ◽

Infinitesimal Transformations ◽

Conserved Currents

The purpose of this chapter is to recall the principles of Lagrangian and Hamiltonian classical mechanics. Many results are presented without detailed proofs. We obtain the Euler–Lagrange equations of motion, and show the equivalence with Hamilton’s equations. We derive Noether’s theorem and show the connection between symmetries and conservation laws. These principles are extended to a system with an infinite number of degrees of freedom, i.e. a classical field theory. The invariance under a Lie group of transformations implies the existence of conserved currents. The corresponding charges generate, through the Poisson brackets, the infinitesimal transformations of the fields as well as the Lie algebra of the group.

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Vakonomic Constraints in Higher-Order Classical Field Theory

10.1063/1.3479312 ◽

2010 ◽

Author(s):

Cédric M. Campos ◽

Manuel Asorey ◽

Jesús Clemente-Gallardo ◽

Eduardo Martínez ◽

José F. Cariñena

Keyword(s):

Field Theory ◽

Classical Field Theory ◽

Higher Order ◽

Classical Field

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A gauge-theoretical approach to elasticity with microrotations

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2011.0718 ◽

2012 ◽

Vol 468 (2141) ◽

pp. 1391-1407 ◽

Cited By ~ 8

Author(s):

C. G. Böhmer ◽

Yu. N. Obukhov

Keyword(s):

Field Theory ◽

Elasticity Theory ◽

Theoretical Approach ◽

Gauge Theories ◽

Equations Of Motion ◽

Classical Field Theory ◽

Classical Field

We formulate elasticity theory with microrotations using the framework of gauge theories, which has been developed and successfully applied in various areas of gravitation and cosmology. Following this approach, we demonstrate the existence of particle-like solutions. Mathematically, this is due to the fact that our equations of motion are of sine-Gordon type and thus have soliton-type solutions. Similar to Skyrmions and Kinks in classical field theory, we can show explicitly that these solutions have a topological origin.

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On the geometric structure of classical field theory in Lagrangian formulation

Mathematical Proceedings of the Cambridge Philosophical Society ◽

10.1017/s0305004100046284 ◽

1970 ◽

Vol 68 (2) ◽

pp. 475-484 ◽

Cited By ~ 31

Author(s):

Jędrzej Śniatycki

Keyword(s):

Field Theory ◽

Conservation Laws ◽

Geometric Structure ◽

Classical Field Theory ◽

Higher Order ◽

Classical Field ◽

Lagrangian Formulation ◽

Symmetry Transformations

AbstractGeometric structure of classical field theory in Lagrangian formulation is investigated. Symmetry transformations with generators depending on higher-order derivatives are considered and the corresponding conservation laws are obtained.

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Classical field theories from Hamiltonian constraint: Canonical equations of motion and local Hamilton–Jacobi theory

International Journal of Geometric Methods in Modern Physics ◽

10.1142/s0219887816500729 ◽

2016 ◽

Vol 13 (06) ◽

pp. 1650072 ◽

Cited By ~ 1

Author(s):

Václav Zatloukal

Keyword(s):

Field Theory ◽

Configuration Space ◽

Equations Of Motion ◽

Classical Field Theory ◽

Classical Field ◽

Hamiltonian Constraint ◽

Hamiltonian Mechanics ◽

Weyl Scalar ◽

Hamilton Jacobi Equation ◽

General Method

Classical field theory is considered as a theory of unparametrized surfaces embedded in a configuration space, which accommodates, in a symmetric way, spacetime positions and field values. Dynamics is defined by a (Hamiltonian) constraint between multivector-valued generalized momenta, and points in the configuration space. Starting from a variational principle, we derive local equations of motion, that is, differential equations that determine classical surfaces and momenta. A local Hamilton–Jacobi equation applicable in the field theory then follows readily. The general method is illustrated with three examples: non-relativistic Hamiltonian mechanics, De Donder–Weyl scalar field theory, and string theory.

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Stringlike solitons in toroidal coordinates

Canadian Journal of Physics ◽

10.1139/p79-082 ◽

1979 ◽

Vol 57 (4) ◽

pp. 590-592 ◽

Cited By ~ 3

Author(s):

J. G. Williams

Keyword(s):

Field Theory ◽

Equations Of Motion ◽

Classical Field Theory ◽

Finite Energy ◽

Classical Field ◽

Toroidal Coordinates ◽

Three Space

A classical field theory is studied in three space dimensions for the case in which the field variables range over a 2-sphere. Toroidal coordinates are found to be the most natural and lead to separation in the equations of motion. A number of finite energy solutions are indicated and correspond to structures extended in space.

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