Light bending from eikonal in worldline quantum field theory

Bastianelli, Fiorenzo; Comberiati, Francesco; Cruz, Leonardo de la

doi:10.1007/jhep02(2022)209

Cited by 23 publications

(17 citation statements)

References 74 publications

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“…The use of an N = 2 supersymmetric extension to the point-particle action to encapsulate spin degrees of freedom [116,117] circumvents the need for a local co-rotating frame. Recent work on the WQFT has included the double copy [118] and applications to light bending [119]; other closely related approaches involve directly solving the classical equations of motion [120] and Wilson line operators [121].…”

mentioning

confidence: 99%

Conservative and radiative dynamics of spinning bodies at third post-Minkowskian order using worldline quantum field theory

Jakobsen¹,

Mogull²

2022

Preprint

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confidence: 99%

Conservative and radiative dynamics of spinning bodies at third post-Minkowskian order using worldline quantum field theory

Jakobsen¹,

Mogull²

2022

Preprint

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“…(2.8) by attempting to write it as a worldline action, following a procedure similar to that of ref. [104]. Up to total derivatives, the vector QED action for H = 0 can be written as…”

Section: Fixing Zeros Of H and H Parametersmentioning

confidence: 99%

Spin supplementary condition in quantum field theory, Part I : covariant SSC and physical state projection

Kim¹,

Steinhoff²

2023

Preprint

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The spin supplementary conditions are constraints on spin degrees of freedom in classical relativity which restricts physical degrees of freedom to rotations. It is argued that the equivalent constraints in quantum field theory are the projection conditions on polarisation tensors, which remove timelike/longitudinal polarisations from the physical spectrum. The claim is supported by three examples of massive spinning particles coupled to electromagnetism: Dirac and Proca fields in quantum field theory, and N = 1 worldline QFT for classical worldline theory. This suggests a resolution to the apparent discrepancy between effective field theory description of massive higher-spin fields [1, 2] and post-Newtonian effective field theory of spinning classical particles [3], where the former admits more unfixed parameters compared to the latter; the additional parameters are fixed by projection conditions and therefore are not tunable parameters.

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“…WQFT is expected to have the potential of capturing such generating functions too. The classical eikonal phase can be obtained from WQFT in various contexts up to 2PM/next-to-leading order (NLO) [43,49,59,60]. However, the calculation of the eikonal phase at 3PM and beyond in WQFT remains somewhat ambiguous in the iǫ-prescription of the worldline propagator, due to the lack of a "natural" time order, as opposed to in the cases of the momentum impulse and spin kick.…”

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confidence: 99%

Binary Dynamics from Worldline QFT for Scalar-QED

Wang¹

2022

Preprint

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We investigate the worldline quantum field theory (WQFT) formalism for scalar-QED and observe that a generating function emerges from WQFT, from which the scattering angle ensues. This generating function bears important similarities with the radial action in that it requires no consideration of exponentiation of lower-order contributions. We demonstrate the computations of this generating function and the resulting scattering angle of a binary system coupled to electromagnetic field up to the third order in the Post-Minkowskian expansion (3PM).

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Light bending from eikonal in worldline quantum field theory

Cited by 23 publications

References 74 publications

Conservative and radiative dynamics of spinning bodies at third post-Minkowskian order using worldline quantum field theory

Conservative and radiative dynamics of spinning bodies at third post-Minkowskian order using worldline quantum field theory

Spin supplementary condition in quantum field theory, Part I : covariant SSC and physical state projection

Binary Dynamics from Worldline QFT for Scalar-QED

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