6/27/00 List of Run II Electroweak Theses Of course there are many styles of theses. Style depends on whether the result is a precision measurement, a measurement, or a limit, on the number of signal events and on the expected amount of background. The delineations are not exactly cut-and-dried. All kinds of analyses are available in the electroweak group. This list is meant to give people a taste of theses that are available. It isn't meant to be comprehensive so if you want to do something not on this list, come and talk to us. Tom and Armand "Measurements" and "Precisions Measurements" and "Limits" W asymmetry Forward-backward W+ vs W- measures quark and antiquark parton distributions. This result is input necessary for W mass. Electrons and muons. Lots of events. 100-200 pb-1 and 2 fb-1. W pT Spectrum A test of production model. Results are input necessary for W mass. Lots of events. Electrons and muons, I think. 200 pb-1 and 2 fb-1. Z pT Spectrum A test of production model. Results are input necessary for W mass. Lots of events but 1/10th number of W's. Electrons and muons. 200 pb-1 and 2 fb-1. W Mass in electron decay mode: Lots of events, small background. Result from M_T(ev) and maybe p_T(e) and maybe p_T(v) available in ~ 200 pb-1. High precision result available in 2 fb-1. Z Forward/Backward Asymmetry Measures sin^2(theta_W). Electrons and muons. Lots of events but 1/10th as many as W's. 100-200 pb-1 and 2 fb-1. W Width Direct and Indirect. Direct uses tail of mT(W) distribution and is independent of theoretical uncertainty in production model. Indirect uses R=sigma.b(W->lv)/sigma.b(Z->ll) and theoretical input on production. 200 pb-1 and 2 fb-1. W and Z Cross Sections Both electron, muon, and tau cross sections are possible. Plenty of events. Drell-Yan Cross Section Dilepton invariant mass spectrum to highest possible mass. Running the Tevatron at 2000 GeV makes this interesting in first 100 pb and in 2 fb-1. W Rare Decays CDF measured ratio of W->pi-gamma/W->lnu limit in Run 1. SM is b.f. of 10-8. Wgamma->evgamma and mvgamma ~120 events per 100 pb-1. 20%-ish background from jets that mimic photons. First observation of the "radiation zero" is available. 100-200 pb-1 and 2 fb-1. Electrons and muons. WW->dileptons 5-10 events per 100 pb-1. Signal-to-background ~3:1. Measure cross section and limit anomalous trilinear couplings. 100-200 pb-1 and 2 fb-1. WZ->trileptons Measure cross section and limit trilinear couplings. Electrons and muons. ~ 1 event per 100 pb-1. Signal to background is 2:1-ish. 200 pb-1 for a limit and 2 fb-1 for cross section. WZ->lvbbbar We should expect ~250 signal events in 2 fb-1, not counting eff'y and acceptance. The higher branching fraction may makes this better than trileptons for anomalous trilinear couplings. This is a bit of a wild card in that it may provide the cleanest Z->bbbar signal. WW/WZ -> lvjj Big background, small signal anomalous trilinear coupling analysis that we did a couple times in Run I. Zgamma->llgamma In the charged lepton mode (electrons and muons) we had ~31 of these in Run I with a 20%-ish background. We limited anomalous trilinear couplings. In the neutrino decay mode we had a signal to background of ~1:1 (if I recall) and also limited anomalous trilinear couplings. We do especially well in Zgamma at the Tevatron. Zgamma->bbbargamma This is a also bit of a wild card. 2 fb-1 gives us ~1000 signal events with a background equal-to or bigger from jets and photons. Certainly provides anomalous coupling limits. May provide us with suprises. ZZ Production CDF saw one 4 lepton event in Run 1. We can expect to see a few in 200 fb-1. Provides anomalous coupling limits. WWgamma and Wgammagamma Production Yeah, the SM can do this. It should be interesting for anomalous quadrilinear coupling analyses in 2 fb-1 and maybe sooner if we are clever. Pushing the photon Et spectrum down to 5 GeV or lower makes a big difference in the cross section for signal. I wondor if this has some bearing on M(W) in case W or decay products radiate 2 photons.