4.7 Article

Preserving new physics while simultaneously unfolding all observables

Journal

PHYSICAL REVIEW D
Volume 104, Issue 7, Pages -

Publisher

AMER PHYSICAL SOC
DOI: 10.1103/PhysRevD.104.076027

Keywords

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Funding

  1. U.S. Department of Energy (DOE), Office of Science [DE-AC02-05CH11231]
  2. National Science Foundation [PHY-2019786]
  3. U.S. DOE Office of High Energy Physics [DE-SC0012567]

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The study investigates how to preserve information about physics beyond the Standard Model through full phase space unfolding, particularly in exotic Higgs boson decays with high signal cross section at the LHC. It reveals that information about new physics is visible in the unfolded data when the signal cross section is high, but in some cases, the unfolding may not work fully or precisely. This research serves as an important benchmark for enhancing unfolding methods for the LHC and beyond.
Direct searches for new particles at colliders have traditionally been factorized into model proposals by theorists and model testing by experimentalists. With the recent advent of machine learning methods that allow for the simultaneous unfolding of all observables in a given phase space region, there is a new opportunity to blur these traditional boundaries by performing searches on unfolded data. This could facilitate a research program where data are explored in their natural high dimensionality with as little model bias as possible. We study how the information about physics beyond the Standard Model is preserved by full phase space unfolding using an important physics target at the Large Hadron Collider (LHC); exotic Higgs boson decays involving hadronic final states. We find that if the signal cross section is high enough, information about the new physics is visible in the unfolded data. We will show that in some cases, quantifiably all of the high-level information about the new physics is encoded in the unfolded data. Finally, we show that there are still many cases when the unfolding does not work fully or precisely, such as when the signal cross section is small. This study will serve as an important benchmark for enhancing unfolding methods for the LHC and beyond.

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