Assessing Calorimeter Requirements for a 100 TeV Future Collider With Reference to New Physics Benchmarks

Plans for a future 100 TeV circular collider require the design of detection equipment capable of measuring events at such high energy. This study examined the simulated decay of hypothetical 10 TeV excited quarks in 100 TeV pp collisions with regard to the possibility of calorimeter punch-through. Two methods of parameterizing the energy resolution in detector simulations were employed to model the effects of particles escaping the hadronic calorimeter. Varying the constant term of the energy resolution parameterization caused the dijet mass distribution to broaden up to 58% with respect to the ATLAS default. Using the assumption that the jets' makeup could be approximated by 180 GeV pions, their expected signal degradation in calorimeters of varying depths was compared to the varied constant term trials. It was found that the broadening associated with a calorimeter of thickness 7 lambda was consistent with that caused by an increase of 1\% in the constant term (from the ATLAS default).