Exploring requirements and detector solutions for FCC-ee

TL;DR

This paper discusses the requirements and potential detector solutions for FCC-ee, focusing on optimizing detector design to meet physics goals and systematic precision, while considering multiple interaction point configurations and potential new particle signatures.

Contribution

It provides an analysis of detector requirements and explores design options for FCC-ee to optimize physics performance and systematic control.

Findings

Benchmark physics processes inform detector performance requirements.

Data-driven methods for detector stability and alignment are studied.

Potential for new detector designs to enhance discovery of weakly coupled particles.

Abstract

Circular colliders have the advantage of delivering collisions to multiple interaction points, which allow different detector designs to be studied and optimized - up to four for FCC-ee. On the one hand, the detectors must satisfy the constraints imposed by the invasive interaction region layout. On the other hand, the performance of heavy-flavour tagging, of particle identification, of tracking and particle-flow reconstruction, and of lepton, jet, missing energy and angular resolution, need to match the physics programme and the exquisite statistical precision offered by FCC-ee. During the FCC feasibility study (2021-2025), benchmark physics processes will be used to determine, via appropriate simulations, the requirements on the detector performance or design that must be satisfied to ensure that the systematic uncertainties of the measurements are commensurate with their statistical precision. The usage of the data themselves, in order to reach the challenging goals on the stability and on the alignment of the detector, in particular for the programme at and around the Z peak, will also be studied. In addition, the potential for discovering very weakly coupled new particles, in decays of Z or Higgs bosons, could motivate dedicated detector designs that would increase the efficiency for reconstructing the unusual signatures of such processes. These studies are a crucial input to the further optimization of the two concepts described in the Conceptual Design Report, CLD, and IDEA, and to the development of new concepts which might actually prove to be better adapted to the FCC-ee physics programme, or parts thereof.