Lagrangian approach to the physical degree of freedom count

Díaz, Bogar; Higuita, Daniel; Montesinos, Merced

doi:10.1063/1.4903183

Cited by 16 publications

(39 citation statements)

References 22 publications

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“…Recall that a first class constraint is one that yields a vanishing Poisson bracket with all of the constraints in the theory, whereas a second class constraint does not. It is worth noting that in [28] an alternative expression to (5) was developed for particle systems, which depends solely on Lagrangian quantities, including the off-shell gauge generators. The result was later on adapted to field theories in [29].…”

Section: Axiomatizationmentioning

confidence: 99%

Maxwell-Proca theory: Definition and construction

et al. 2020

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We present a systematic construction of the most general first order Lagrangian describing an arbitrary number of interacting Maxwell and Proca fields on Minkowski spacetime. To this aim, we first formalize the notion of a Proca field, in analogy to the well known Maxwell field. Our definition allows for a non-linear realization of the Proca mass, in the form of derivative self-interactions. Consequently, we consider so-called generalized Proca/vector Galileons. We explicitly demonstrate the ghost-freedom of this complete Maxwell-Proca theory by obtaining its constraint algebra. We find that, when multiple Proca fields are present, their interactions must fulfill non-trivial differential relations in order to ensure the propagation of the correct number of degrees of freedom. These relations had so far been overlooked, which means previous multi-Proca proposals generically contain ghosts. This is a companion paper to arXiv:1905.06968 [hep-th]. It puts on a solid footing the theory there introduced.

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Section: Axiomatizationmentioning

confidence: 99%

Maxwell-Proca theory: Definition and construction

et al. 2020

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“…Furthermore, it was also shown in Ref. 10 that the Lagrangian formula can be cast in geometric terms such as N − 1 2 (l + g + e) = 1 2 Rank (ι * Ω) ,…”

Section: The Geometric Lagrangian Approachmentioning

confidence: 95%

“…6 The constraint algorithm generates a sequence of sub-manifolds T C =: P 1 ⊇ P 2 ⊇ P 3 ⊇ · · · which are defined by the Lagrangian constraints ϕ ′ s (many of them are actually part of the equations of motion). 6,10 The algorithm must end (if the theory is well-defined) at some final constraint submanifold P := P s = ∅, 1 ≤ s < ∞. Thereby, on P , we have completely consistent Lagrange's equations of motion…”

Section: A Algorithm To Obtain the Lagrangian Constraints (Constrainmentioning

confidence: 99%

Geometric Lagrangian approach to the physical degree of freedom count in field theory

Díaz

Montesinos

2018

Journal of Mathematical Physics

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1To circumvent some technical difficulties faced by the geometric Lagrangian approach to the physical degree of freedom count presented in the work of Díaz, Higuita, and Montesinos [J. Math. Phys. 55, 122901 (2014)] that prevent its direct implementation to field theory, in this paper, we slightly modify the geometric Lagrangian approach in such a way that its resulting version works perfectly for field theory (and for particle systems, of course). As in previous work, the current approach also allows us to directly get the Lagrangian constraints, a new Lagrangian formula for the counting of the number of physical degrees of freedom, the gauge transformations, and the number of first-and second-class constraints for any action principle based on a Lagrangian depending on the fields and their first derivatives without performing any Dirac's canonical analysis. An advantage of this approach over the previous work is that it also allows us to handle the reducibility of the constraints and to get the off-shell gauge transformations. The theoretical framework is illustrated in 3-dimensional generalized general relativity (Palatini and Witten's exotic actions), Chern-Simons theory, 4-dimensional BF theory, and 4-dimensional general relativity given by Palatini's action with cosmological constant.

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“…These are, by the converse of Noether's second theorem, in one-to-one correspondence with gauge symmetries, which one can then explicitly obtain [28]. The relation with the degree of freedom counting in the Hamiltonian formalism can be seen by noting that the number of second class Hamiltonian constraints is given by l + g − e and the number of first class Hamiltonian constraints equals e. Also, the total number of gauge identities g equals the number of primary first class constraints in the Hamiltonian analysis; see again [26][27][28][29].…”

Section: Jhep07(2016)130mentioning

confidence: 99%

“…gauge identities. After the termination of this algorithm, the number of degrees of freedom present in the theory can be computed to be [26][27][28][29] …”

Section: Jhep07(2016)130mentioning

confidence: 99%

Exorcising the Ostrogradsky ghost in coupled systems

Klein

Roest

2016

J. High Energ. Phys.

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The Ostrogradsky theorem implies that higher-derivative terms of a single mechanical variable are either trivial or lead to additional, ghost-like degrees of freedom. In this letter we systematically investigate how the introduction of additional variables can remedy this situation. Employing a Lagrangian analysis, we identify conditions on the Lagrangian to ensure the existence of primary and secondary constraints that together imply the absence of Ostrogradsky ghosts. We also show the implications of these conditions for the structure of the equations of motion as well as possible redefinitions of the variables. We discuss applications to analogous higher-derivative field theories such as multi-Galileons and beyond Horndeski.

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Lagrangian approach to the physical degree of freedom count

Cited by 16 publications

References 22 publications

Maxwell-Proca theory: Definition and construction

Maxwell-Proca theory: Definition and construction

Geometric Lagrangian approach to the physical degree of freedom count in field theory

Exorcising the Ostrogradsky ghost in coupled systems

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