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Unambiguously Testing Positivity at Lepton Colliders.

Jiayin Gu1,2,3, Lian-Tao Wang4,5, Cen Zhang6,7

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This summary is machine-generated.

Future lepton colliders can test fundamental quantum field theory principles using the diphoton (γγ) channel. Positivity bounds on dimension-eight operators offer a clear test of these principles, impacting global analyses.

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Area of Science:

  • High Energy Physics
  • Quantum Field Theory
  • Collider Physics

Background:

  • The diphoton (γγ) production at lepton colliders (e^{+}e^{-}(μ^{+}μ^{-})→γγ) is sensitive to dimension-eight operators in new physics scenarios.
  • These dimension-eight operators are constrained by positivity bounds derived from fundamental quantum field theory principles like unitarity and Lorentz invariance.

Purpose of the Study:

  • To investigate the capability of future lepton colliders in probing dimension-eight operators via the diphoton channel.
  • To assess the effectiveness of positivity bounds as a direct and unambiguous test of fundamental quantum field theory principles.

Main Methods:

  • Analysis of the diphoton cross section as a direct observable sensitive to dimension-eight operators.
  • Estimation of the sensitivity of various future lepton colliders to these operators and their associated positivity bounds.
  • Exploration of the impact of positivity bounds on global effective field theory analyses.

Main Results:

  • Positivity bounds provide a robust and unambiguous test of quantum field theory principles in the diphoton channel.
  • Future lepton colliders show significant potential for probing dimension-eight operators and testing these bounds.
  • Positivity bounds can resolve degeneracies in effective operator parameter spaces, refining global analyses.

Conclusions:

  • The diphoton channel at lepton colliders offers a unique window into new physics and fundamental principles.
  • Positivity bounds are a powerful tool for constraining new physics and validating quantum field theory.
  • Future collider experiments will play a crucial role in testing these bounds and advancing our understanding of fundamental physics.