Physics Requirements for Calorimetry at a Linear Collider André S. Turcot

1. Physics Requirements for Calorimetry at a Linear Collider André S. Turcot Brookhaven National Lab Santa Cruz Linear Collider Retreat June 27-30 2002 UCSC Linear Collider Retreat

2. Overview • There are key physics processes that set the performance requirements for the Linear Collider Calorimetry • In many cases, measurements will be statistics limited • To fully exploit the physics potential of the machine we will have to consider fully hadronic final states • In the following, I will try to give an overview of those processes where calorimetry will play a key role UCSC Linear Collider Retreat

3. Physics Benchmarks • Higgs: • Precision Higgs physics will be statistics limited • Use of hadronic Z decays will be necessary • ElectroWeak: • Separation of Hadronic Gauge Boson Decays • Why? We must adopt the paradigm that the W/Z is a fundamental particle equivalent to the photon • Top Quark: • Reconstruction of 6 jet final states • Jet Energy Resolution/Reconstruction • SUSY Searches: Hermiticity, Missing ET Resolution • Precision EW: Luminosity Profile UCSC Linear Collider Retreat

4. Energy Resolution? • Energy Resolution is not the true figure of merit • Physics is driven by jet resolution • e.g. D0 U/AR e/h = 1 • (EM) = 15%/E • (pion)  50%/E • Yet (jet)  80%-100%/E Calorimeter design should be guided by Jet Energy Resolution Current State of the Art is Energy Flow Analysis Requires highly segmented tracking calorimetry UCSC Linear Collider Retreat

5. Hermeticity • Hermeticity enters in two key roles • Determination of the event missing energy • Tagging of scattered beam particles • SUSY drives the hermeticity issue • Two photon, ee -> eeff backgrounds will be problematic • Scattered e(s) in ee -> ee X can easily produce missing ET • ET(max) = EBEAM x sin  where  defines calorimeter fiducial • For 500 GeV and 40 mrad coverage, ETMISS can be up to 10 GeV Hermeticity in forward region will be crucial UCSC Linear Collider Retreat

6. ZH WW Higgs Physics • Measurement of the hWW coupling requires separation vvh and Zh production channels • Missing mass is discriminating variable • e.g. BR(h->WW*) • Degrading the jet resolution from 30% to 60% corresponds to a factor 2 in luminosity • hZ production with hadronic Z final states have a large impact UCSC Linear Collider Retreat

7. Higgs Physics Self Coupling • Flagship measurement for a Linear Collider • Verify shape of potential • Does the Higgs generate its own mass? • Critically depends on the calorimeter performance • 6j final state with 4 b jets • For 1 ab-1 and 60%/E jet resolution -> 3 sigma signal, • For 30%/E -> 6 sigma signal • Evidence vs. a measurement UCSC Linear Collider Retreat

8. SUSY and Calorimetry • Consider two possible SUSY scenarios • “High” tan scenarios • multiple soft tau leptons • Tau ID could be a driving issue • Hermeticity will be critical as the ee xsec is enormous • Measurement of the tau polarization in cascade decays will provide a key insight • “Small” Gaugino mass differences: O(5) GeV • Small visible mass in final states! • Hermeticity in forward region again will be the critical issue • Irreducible eeqq bckgnds will require excellent visible mass resolution to isolate signal UCSC Linear Collider Retreat

9. Further SUSY Considerations • Given that the SUSY breaking mechanism is a black box, we must be prepared for surprises • GMSB scenarios can produce non-pointing photons • Rely on calorimeter to determine Impact Parameter • Measure Gaugino lifetime (key input to any theory) • Quasi-degenerate Gauginos • Small visible mass, hermeticity will be essential UCSC Linear Collider Retreat

10. Tau Physics • The Tau lepton will be a sensitive polarimeter for LC physics • However, most processes will be statistics limited • LEP expts. had 200K tau pairs, we will not be so blessed • Need ability to cleanly separate v and v final states • Could be critical depending on physics scenario that is realized • Tests of CP violation in Higgs decays • Stau NLSP scenarios • High tan solutions • Z’ effects for 3rd generation • More mundane level, tau ID and controlling jet fake rates • What is acceptable fake rate? 10-3 ? UCSC Linear Collider Retreat

11. Gauge Boson Scattering • Measurement of the WL WL scattering amplitudes • Must cleanly distinguish between evWZ, vvZZ and vvWW using purely hadronic final states • relying on leptonic final states is not possible • Uninteresting evWZ 4x larger • Going from 30%/E to 60%/E corresponds to loosing 45% of the integrated L (Brient) evWZ vvWW vvZZ UCSC Linear Collider Retreat

12. Gauge Boson Identification Videau, Calor2002 UCSC Linear Collider Retreat

13. Top Quark Physics • Precise measurement of the Top Quark mass • There are two complementary techniques • Direct measurement above threshold (pole mass) • Requires good jet reconstruction efficiency • “Bootstrap” reconstruction • find jet pairs -> W, W+b -> top • Hadronic W mass resolution is important • Suppress 6-f final states and combinatorics • Recall LEP W mass measurement (4 jets -> 3 pairings) • Threshold scan requires precise dL/dE spectrum • Places premium on small angle bhabha scattering UCSC Linear Collider Retreat

14. Timing Considerations • Depending on choice of machine technology timing information from the calorimeter may be necessary • Consider beam bunch structure • Tesla: 300 ns spacing in 1 ms trains @ 5 Hz • NLC/JLC: 2ns spacing in 300 ns trains @ 180 Hz • May need to suppress contribution from 2-photon events in different bunches • Topologies such at () ETmiss require ability to veto cosmics • Depends details of signal integration times • Time-of-flight may be useful for quasi-stable massive charged particles UCSC Linear Collider Retreat

15. Conclusions • To fully realize the physics potential of a linear collider we will have to rely reconstructing fully hadronic final states • Given the fundamental nature of the W and Z bosons we must accept a new paradigm that they must be fully reconstructable and distinguishable in complex events • In many key physics processes, the figure of merit is the jet energy resolution • Our current understanding of jet energy resolution points to a solution relying upon an Energy Flow Algorithm • Any proposed calorimeter must be amenable to the implementation of an Energy Flow analysis UCSC Linear Collider Retreat