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Arbitrary p-form Galileons

2 Pith papers cite this work. Polarity classification is still indexing.

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abstract

We show that scalar, 0-form, Galileon actions --models whose field equations contain only second derivatives-- can be generalized to arbitrary even p-forms. More generally, they need not even depend on a single form, but may involve mixed p combinations, including equal p multiplets, where odd p-fields are also permitted: We construct, for given dimension D, general actions depending on scalars, vectors and higher p-form field strengths, whose field equations are of exactly second derivative order. We also discuss and illustrate their curved-space generalizations, especially the delicate non-minimal couplings required to maintain this order. Concrete examples of pure and mixed actions, field equations and their curved space extensions are presented.

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gr-qc 1 hep-th 1

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2026 1 2019 1

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UNVERDICTED 2

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Radial Solutions of Multi-Field de Sitter Galileons

hep-th · 2026-06-29 · unverdicted · novelty 6.0

Derives conditions for viable screened radial solutions in multi-field de Sitter Galileons, showing curvature can mitigate superluminality at the cost of a finite validity range set by the strong-coupling point.

Noncanonical Approaches To Inflation

gr-qc · 2019-06-21 · unverdicted · novelty 3.0

A review thesis covering Mukhanov parametrization, general scalar-tensor theories, and new slow-roll techniques for canonical and noncanonical inflation observables.

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  • Radial Solutions of Multi-Field de Sitter Galileons hep-th · 2026-06-29 · unverdicted · none · ref 56 · internal anchor

    Derives conditions for viable screened radial solutions in multi-field de Sitter Galileons, showing curvature can mitigate superluminality at the cost of a finite validity range set by the strong-coupling point.