Conveners
Physics and Detectors: Track 3
- Marcel Vos (IFIC (UV-CSIC))
- Roman Poeschl (IJCLab)
- Karsten Buesser (DESY)
- Frank Simon (KIT)
- Dylan Rankin (MIT)
- Andrew White (University of Texas at Arlington (US))
Physics and Detectors: Track 3
- Roman Poeschl (IJCLab)
- Andrew White (University of Texas at Arlington (US))
- Marcel Vos (IFIC (UV-CSIC))
- Dylan Rankin (MIT)
- Karsten Buesser (DESY)
- Frank Simon (KIT)
Physics and Detectors: Track 3
- Karsten Buesser (DESY)
- Andrew White (University of Texas at Arlington (US))
- Frank Simon
- Dylan Rankin (MIT)
- Marcel Vos (IFIC (UV-CSIC))
- Roman Poeschl (IJCLab)
Physics and Detectors: Track 3
- Karsten Buesser (DESY)
- Dylan Rankin (MIT)
- Roman Poeschl (IJCLab)
- Marcel Vos (IFIC (UV-CSIC))
- Andrew White (University of Texas at Arlington (US))
- Frank Simon (KIT)
Physics and Detectors: Track 3
- Karsten Buesser (DESY)
- Dylan Rankin (MIT)
- Roman Poeschl (IJCLab)
- Andrew White (University of Texas at Arlington (US))
- Marcel Vos (IFIC (UV-CSIC))
Silicon pixel trackers are at the heart of all modern collider physics design, providing high-quality position measurements close to the beamline and forming the core of modern heavy-flavor tagging algorithms. Recent advances in both silicon pixel size and techniques for rendering machine learning algorithms into hardware allow detailed information about the ionization charge deposition to be...
In light of upgrades such as the High Luminosity LHC (HL-LHC) and proposals for future collider experiments, continued development of particle tracking technology is crucial. Monolithic Active Pixel Sensors (MAPS) are established vertex detectors, which combine the readout electronics and sensitive volume in one sensor, providing excellent spatial resolution, while maintaining a low power...
The detectors at future e+e- linear colliders will need unprecedented precision on Higgs physics measurements. These ambitious physics goals translate into very challenging detector requirements on tracking and calorimetry. High precision and low mass trackers, as well as highly granular calorimeters, will be critical for the success of the physics program. To develop the next generation of...
A large, worldwide community of physicists is working to realize
an exceptional physics program of energy-frontier, electron-positron
collisions with the International Linear Collider (ILC)
and other collider projects (summarized and evaluated in
https://arXiv.org/abs/2208.06030).
The International Large Detector (ILD) is one of the proposed detector concepts at the next \ee collider....
Reaching the physics goals of future $e^+e^-$ colliders requires excellent detectors and software tools optimized towards the highest precisions.
The CLD detector model establishes a conservative baseline for an experiment for the proposed FCC-ee collider.
However, the quickly evolving silicon-detector landscape will allow building a detector with parameters beyond the currently established...
The International Large Detector (ILD) is a detector designed primarily for the International Linear Collider (ILC), a high-luminosity linear electron-positron collider with an initial center-of-mass energy of 250 GeV, extendable to 1 TeV.
The ILD concept is based on particle flow for overall event reconstruction, which requires outstanding detector capabilities including superb tracking,...
Construction and assembly of future Higgs Factory detectors is a complex endeavour and the related time lines might be longer than anticipated. In recent years, possible assembly scenarios for the ILD detector concept at the ILC have been studied in some detail. I will summarise the results which might be interesting for other detectors at future Higgs Factories.
Large detector solenoids are crucial for all future Higgs Factory detectors. Since the production of the last big magnets, industry has cut its capacities for the production of aluminum stabilised conductors which represent the accepted standard technology for big detector magnets.
A workshop at CERN in September 2022 brought together experts from detectors, magnet designers, and industry....
In preparing to secure commitments to approve the ILC in Japan, the ILC International Design Team (IDT) has identified a prioritized list of critical R&D Work Packages (WPs) that should be pursued in a timely matter. Among these WPs, WP-16 has been identified by an ICFA sponsored Machine Advisory Committee review as having very high priority. WP-16 consists of two sub-tasks with the first task...
Future Higgs factory experiments will require high precision in the jet reconstruction, particle identification and event tagging, all challenges which can addressed by ultra-granular calorimeters, associated with high-precision tracking and performant Particle Flow reconstruction. The technical issues of large ultra-granular calorimeters are numerous, and maximal for the electro-magnetic...
Most future high energy $e^{+}e^{-}$ colliders proposals consider using high granular calorimeters in their detectors concepts. One of such high granular calorimeters proposals silicon-tungsten electromagnetic calorimeter (SiW-ECAL) designed and constructed by the CALICE Collaboration. Its key features are: unprecedented high granularity and compactness featuring very low power consumption. ...
J. Va’vra, A.G. Schwartzman, V. Cairo, M. Basso and Su Dong
One important physics goal of future Higgs Factories is to probe the Higgs coupling to strange quarks. This requires the design of a specialized Ring Imaging Cherenkov (RICH) detector that can provide pi/K separation up to 30-50 GeV. In this talk, we present studies of a RICH system that operates at 5 Tesla. We find that the...
Calorimeters optimised for particle flow feature a high segmentation in both longitudinal and transversal direction. The tendency for future Higgs factories is an increase of the beam collision frequency compared to the case of the International Linear Collider (Bunch trains with a repetition rate of 5-10 Hz). For example at circular e+e- colliders as the FCCee the envisaged bunch distance is...
The concept of a digital electromagmetic calorimeter using MAPS sensors as the active layers has been demonstrated using the EPICAL-2 prototype, a 24 layer, ~20 radiation length device. Each layer has an active area of $30\times 30~\mathrm{mm^2}$ provided by two ALPIDE sensors. Final results characterising the performance in terms of energy resolution, linearity and lateral shower profile...
Calorimeters for future colliders will need unprecedented energy and timing resolution, as well as particle identification capabilities. Our collaboration, CalVision,a collaboration of scientist from FNAL, Argonne, Caltech, Maryland, Michigan, Milano-Bicocca, MIT, Oak Ridge, Princeton, Purdue, Texas Tech, and Virginia, is working on making maximal use of available information to enable this...
We propose a sandwich calorimeter which aims at both ECAL and HCAL for the future collider experiments. It consists of Lead glass layers and Glass scintillator layers of sandwich structure where both layers are active for Cherenkov and scintillation lights respectively. The materials are chosen to be the calorimeter as inexpensive as possible. The expected energy resolution for high energy...
