OUTLINE The Chicago Involvement in CDF Run II Activities, Future Plans Early History Hardware: L1,...
-
date post
21-Dec-2015 -
Category
Documents
-
view
217 -
download
2
Transcript of OUTLINE The Chicago Involvement in CDF Run II Activities, Future Plans Early History Hardware: L1,...
OUTLINE• The Chicago Involvement in CDF
• Run II Activities, Future Plans
•Early History
•Hardware: L1, L2, Fred, Trigger Systems; BBC,SVT•People- former students, postdocs- training…•Physics Analysis Topics
•Carla - Level 1 Care and Feeding•Run II Upgrades- Level 2, TDC, EM Timing•Physmon - Real-Time Feedback•Run II Analyses- top dileptons, taus (charged Higgs) , photons (GSMB); SM, Bj-E(6), ED, Monte Carlo tools (signature-based searches)•Phenomenology: Moscow, Durham, Fermilab•Instrumentation development- picosec TOF (Tim)
Fundamental Tenets (style)
• Strength comes from working together
•Common interests in hardware, physics
•Build common analysis tools, datasets, computing infrastructure; share knowledge
•Share (big) load of detector maintenance
•Students, postdocs integrated into Eshop (and formerly, mechanical design)
• Undergrads are colleagues
Historic UC Roles on CDF
• Intellectually Challenging Detector System Design and Construction-new capabilities- need the strength to take on and maintain a major system
– Level 1, 2 trigger systems- CDF and CDFII– SVT (with Pisa)– Luminosity BBC system
• Central Physics Issues- leadership analyses
– D* recon(1989), Z mass, W mass, W width, W BR’s, top discovery, top mass, top to H+, GMSB (photons), ED, .. Many innovative analyses first done by UC
• Education/Training –
– Undergrads – deep involvement in real work (e.g. Kopp, Incandela, Nelson,Onyisi,..) – Graduate Students (e.g. Swartz, Roodman, Gerdes, Kopp, Incandela, Saltzberg, Somalwar,..)– Postdocs (e.g. Campagnari, Eno, Sullivan,Campbell, Amidei, Liss,Knuteson, Ashmanskas,….) – High School (Jocelyn Monroe, Tim Credo, Colliness Morris,…)
• Collaboration Leadership
– Mel, Young-Kee –Spokespersons– Many Physics Group Convenorships (EWK, Top, Top Dilepton, Exotics, Trigger, etc…– Now Steve coconvenor of Btag, Silicon Tools; Ivan B-Tools, Carla was recently Dilepton,…
Former CDF Postdocs now faculty/staff Myron Campbell- Michigan (Chair, even)Dan Amidei- MichiganTony Liss- IllinoisClaudio Campagnari- UCSBSarah Eno- MarylandGreg Sullivan- MarylandRay Culbertson (FNAL)Peter Wilson (FNAL)Tsuyoshi Nakaya (Kyoto)Bruce Knuteson- MITMaria Spiropulu- CERNKara Hoffman (1/2)- MarylandTaka Maruyama- Tsukuba
Intro: Fermi’s Yale Lectures of 1951
“Electromagnetic andYukawa InteractionConstants:”
“Perhaps future developments..will enable us to understand the reasons for the existence and the strength of the various interactions.”- Fermi
(Broad interpretation of the early Chicago involvement with CDF)
The Start of CDF• Jan 1977- Jim Cronin heads Colliding Beam
Dept.- -• 2 Init. Designs: one magnetic, one not• Wilson decrees 10M$ cap on detector cost (!)
We say `sure’…• Oct. 78- Wilson resigns- Lederman new Dir.• Oct. 79- CDF Dept formed; Alvin Head of
CDF. Roy joins later, + Dennis Theriot• 1981- Technical Design Report
CDF Trigger- ChicagoTDR (1981!) :
“8.1 General Considerations
The problem presented by the trigger is: at a 50 kilocycle interaction rate, with a typical multiplicity of 50 particles per event, in an environment with unmeasured backgrounds, to pick out the signatures of interesting events in a completely new energy domain. Two additional considerations are that the physics of interest may change during the lifetime of the detector, and that the detector will grow in capability by the addition of new detector technology” Note: now designing for gt
12 megacycle int. rate!
The detector comes to life…82-85
Universities had good mechanical engineering in those days- good student training in mech and elec.
Front plates for central calorimeter modules machined downstairs in our shop
Hans Kautsky (from UC, but by then at Fermilab, in the CDF arches and coil…
Discovery Potential:The Tevatron Complex and CDF-II
Note `goals’ are `Delivered; data points are ‘Published’.
HJF “group” Analysis interests (per request)- former students•Joe Incandela (1986)- Magnetic monopoles (not yet CDF)•Sunil Somalwar (88)- Magnetic monopoles (not yet CDF)•Yeong-Dong Tsai (89)- Dijet high-mass search •Rick Snider (1990)- Min Bias – particle prod •Paul Derwent (90)- W BR’s /W width•Sacha Kopp (94)- W BR’s/W width; direct W width measurement•David Saltzberg (94) W mass (80.410)•Jim Romano (95) Top quark in dileptons•Marcus Hohlmann (97)- Top quark into tau’s, : charged Higgs•Dave Toback (97) - Diphotons and GMSB, signature-based•John Wahl (99)- W BR’s/ W width•Jeff Berryhill (2000)- Photon + lepton; GMSB, signature-based•Collin Wolfe (TBD)- Dilepton signatures- top+new particle search (Bj,ED)•Sasha Paramonov (TBD)- High Pt boson signatures- new particle search•Andrei Loginov (ITEP)- Photon + lepton; GMSB, signature-based
`Top’ Dileptons- 2 e or mu, met, jets
Also to watch- by eye LH looks like CDF Run 1 at large met?
(Carla as Dilepton Co-convenor)
Searching for new physics in dileptons
(Collin,Steve,Carla,Jason,HF)•Looking at 2 models of new physics specifically that would give multiple W, Z’s, giving dileptons
•Comprehensive approach- 0,1,2,3,4,.. Jet; OS/SS, met/nomet; btag, and add tau’s
•Name of game is acceptance- use likelihoods for particle ID, overall selection
•Develop tools for systematic comparing SM expectations to data (with Boos, Dudko)
•Run 1 dilepton data had some distinctly `un-top-like’ qualities (but onesies/twosies)- two neat examples- the top trilepton event, and the ttbar-gamma event, e.g (among other more difficult kinematic/other oddities)
Run 1 “dilepton” event-
3 isolated leptons- one of 182 GeV pt; 116 GeV of met; one jet of 96 GeV
27 GeV Muon
24 GeV Electron
182 GeV Electron
96 GeV Jet
116 GeV Met
Ttbar-gamma One expects gammas at
some rate (Baur, Rainwater)-
this was in 100 pb-1…8 fb-1?
High_Pt photons are characteristic of GMSB, e.g.
High Pt Photons as New Physics Signature: (e.g. CDF Run1 eeevents)
Are Run 1 anomalies real? Experiments see only upward fluctuations- can estimate factor of luminosity needed to get
to the mean (though huge uncert.)
Collin, Carla, Steve, Jason’s dileptons (with tau’s, likelihoods,tags)
OS ee,mumu,emu +njets SS ee,mumu,emu +njets
SS are signatures of (Majorana) gluinos, Servant RS model (multiple WZ bosons, e.g., …)
Unblessed- not to leave `room‘ (please!)
Collin, Carla, Steve, Jason’s dileptons (with tau’s, likelihoods,B-tags)
OS ee,mumu,emu +njets+1 btag
OS ee,mumu,emu +njets+ 2 btags
Unblessed- not to leave `room‘ (please!)
Likelihoods: e, mu,Tau
Idea: Different topologies have different background levels: be able to set rejection levels appropriate for sample, and increase acceptance for these low-rate channels.
Bruce Knuteson developed e, mu and framework code: Sasha is working on the mu, Collin and Carla on e’s, and Steve Levy has updated the e’s, and is working on the tau’s. See’s 30% increase in effic. At same fake rate.
Steve Levy- Tau likelihood (Tau in Red, Jet Blue)
B-taggingSteve is Convenor of B-tag Group; also has made
big contrib. on Layer 00
Using Layer00 gives big improvement in effic
Using Layer00 gives improvement in overall tags
Electron Likelihood: Z mass(Bruce Knuteson, Steve Levy)
e+e- Mass:
Run II Data: 234 pb-1
Red: Both Likelihood and Standard Cuts
Blue: LIkel Only
Green: Standard Only
Gain 20% (!) at same fake rate
SM Dilepton Predictions-MadGraph
•Consistent SM sets
•Allows ratio work (e.g W+njets/Z+njets
•ME has gamma, Z poles (crucial)
•Carries helicities, incl. to tau decay (ditto)
•LO, however; no unified QED/QCD
• Use for our dileptons
• Developed CDF path through sim, prod, ntuple for whole collab
Sasha’s high-pt bosons
W-> mu nu trans mass (170K events)
Z-> mu mu Pt (13K events) N.B.
Bj E(6) and Servant/Agashe ED Models predict high pt W’s and Z’s (and Higgs, in Bj case!)
Unblessed- not to leave `room‘ (please!)
Bj: QQ -> uuWW, udWZ, udWH,ddZZ,ddZH,ddHH
Pt of the Z
Major Effort on Better SM predictions (with Tim Stelzer, Steve
Mrenna, E. Boos, L. Dudko)
Both CompHep and MadGraph Wgg and Zgg; agree to within 5% (no tuning)
Andrei’s Gamma-Lepton+X
Muon+photon+met Electron+photon+met
2 very rare events in Run 1 Berryhill sample- eeggmet and mmggjj- also 2.8 sigma excess (but looked like Wgamma kinematically..)- 5 times data now.. GMSB signature, among..
Unblessed- not to leave `room‘ (please!)
Running, Building, Monitoring
• Upgrades- Level 2 Initiation (Ted Liu, Peter Wittich, Harold, Mircea,…!)
• Upgrades- EM timing- Initiation, cute pickoff, Plug outputs (Toback!)
• Upgrades- New TDC- sweet design, beautiful performance- unhappy ending (but will get used, we hope, by Wah, …)
• Monitoring- Physmon, Carlamon (L1)
Recent muon efficiencies
Collin’s Physmon- Online Fast Feedback from the Express Line with full Production- monitor
physics quantities
Oops…
Oops…
Ratio Wmu/We ; D-Kpi Mass
D-Kpi Mass W-munu/W-enuNeed J/Psi triggers back into Stream A to regain muon monitoring we had…
Oops…Oops?…
Oops…
L1 Trigger Monitoring- Carla
Yesterday’s– one channel has an intermittent one-bit discrepancy trigger-DAQ
The Future• I plan to exploit CDF until it’ s no longer the best game in town
• Have a factor of (maybe) 20 more lum; would be 80 times RunI
•Am interested in instrumentation, accelerators, non-accelerator fundamental measurements (Saltzberg’s stuff is fascinating)
•Picosecond timing, low Et photons- so many things I don’t understand- should keep me busy for 5 years, and then I’ll see what’s most interesting (Nambu)
•Much to be done on MC tools- closer collab with phenomenology- have started with Moscow State, Stelzer, Mrenna (Fermilab)- have been approached by Stirling for a more formal connection- better SM tools essential for LHC
Modelling requires NLO QCD and QED in same MC
Recoil event modelling depends on W Pt at low Pt
Underlying event (uev) is 30 MeV/tower/interaction in CDF- indicates scale of precision needed- must get all detector response to uev from data (i.e. not MC).
Old idea (UA2, CDF Run 1a)- use Z sample to get detector response to recoil. E.g. (D. Saltzberg) for each W from MC use measured recoil from a Z with the same Pt. Limiting factor for using Z’s was factor of 10 smaller X BR.
W Mass Measurement Limited by Theoretical Issues?
Q: Will future require measuring W and Z mass simultaneously by same technique? If so, need QCD/QED NLO, Z/int.., for Z.
A. Focus on W and Z production and higher order differences
Error on W mass has scaled inversely with sqrt of luminosity so far – now at 59 MeV. what are our expectations with 10-20X more data?
Modelling requires NLO QCD and QED in same MC
Underlying event is 30 MeV/interaction in CDF- need to get from data
Recoil event modelling depends on W Pt at low Pt- also need to get response from data
Wish List Item: Answer to Q: What are the theoretical limitations on the ratio of gamma-b(c)/gamma-jet balancing?
Un-Ki Yang, Adam Gibson
Jet energy scale is critical to top mass measurement
B-jets contribute most to mass (don’t have W mass constraint)…
Promising Idea:
Balance photon and b-jets to calibrate response
One of Hardest Problems is precise predictions of W,Z+Njets
Each with at least on tag in this case- this from top crossection meas.
One of Hardest Problems is precise predictions of W,Z+Njets
Lauren Beitler (undergraduate!) from datasets with CKKW matching made by Steve Mrenna– see S. Mrenna and P. Richardson, hep-ph/0312274
Testing the SM- systematically?
Worked closely with E. Boos and L. Dudko on making CompHep better suited for hadron colliders; has evolved into working on developing a theoretically well-grounded basis for distinguishing two processes- e.g. top dileptons from Zee+2jets- collaboration in progress (some UC support)
Red- Zee+2jets
Blue- ttbar->ee
Altera-Stratix 96 Channel TDCHarold Sanders, Mircea Bogdan, Sasha Paramonov, HF
Sweet design- takes advantage of Altera. Sasha’s neat trigger design- XFT
Picosecond TOF(with Tim Credo (IMSA), Harold, Tang)
• Aspen `future talk’ led to thinking about most-needed instrumentation
• Particle ID (!)-
• Can one do picosecond (1 or less) TOF?
• Started with Robert Schroll (theorist, champion mimic) as P335 (course) project
• Continued with Tim Credo (HS) student
• Ongoing collab with Burle Industries
Picosecond Timing- IV
Robert and Tim: Simulation of Cherenkov generation, transmission, photocathode, TTS, anode layout and summing
Leading edge jitter 0.6 psec
•With luck (truly) we have a shot at exploring LOTS of channels, topics, opportunities
•a large region of unexplored kinematic and signature space.
•Big effort now on machine performance
•Detectors working well enough- detailed calibrations still in progress
•Enormous tasks of understanding detectors, SM predictions, at precision levels (new paradigms too)
Conclusions – I’m hopeful: best thing that could happen to US HEP (and world HEP) is a discovery at Fermilab- it’s our main chance.