Clebsch-Lagrange variational principle and geometric constraint analysis of relativistic field theories
Tobias Diez, Gerd Rudolph

TL;DR
This paper introduces a new variational principle inspired by optimal control to analyze relativistic field theories with gauge symmetries, emphasizing geometric and Hamiltonian structures.
Contribution
It develops a novel Clebsch-Lagrange variational framework that captures gauge constraints via momentum maps, unifying several fundamental physical theories.
Findings
Reformulates gauge theories within a geometric variational principle.
Derives gauge constraints as momentum map conditions.
Shows compatibility with Yang-Mills-Higgs and Einstein-Hilbert actions.
Abstract
Inspired by the Clebsch optimal control problem, we introduce a new variational principle that is suitable for capturing the geometry of relativistic field theories with constraints related to a gauge symmetry. Its special feature is that the Lagrange multipliers couple to the configuration variables via the symmetry group action. The resulting constraints are formulated as a condition on the momentum map of the gauge group action on the phase space of the system. We discuss the Hamiltonian picture and the reduction of the gauge symmetry by stages in this geometric setting. We show that the Yang-Mills-Higgs action and the Einstein--Hilbert action fit into this new framework after a -splitting. Moreover, we recover the Gau{\ss} constraint of Yang-Mills-Higgs theory and the diffeomorphism constraint of general relativity as momentum map constraints.
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