1 / 18

Analysis of Semileptonic and Hadronic Decays for Bs0 Oscillation Measurements

This presentation outlines event selection criteria, efficiency enhancements, purity assessments, and measurements of decay length, momentum resolution, and proper time for Bs0 oscillation measurements. Collaborators include D. Abbaneo, S. Armstrong, G. Boix, A. Halley, and F. Palla.

cady
Download Presentation

Analysis of Semileptonic and Hadronic Decays for Bs0 Oscillation Measurements

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Thursday Meeting 2 Mar 2000 Bs0Ds+- events for Bs0 oscillation measurements Andrea Sciaba` With the collaboration of D. Abbaneo, S. Armstrong, G. Boix, A. Halley and F. Palla

  2. Outline • Event selection, efficiency, purity • Decay length, momentum resolution, proper time • Initial state tag, mistag • Data sample • Systematic uncertainties • Conclusions

  3. Event selection • Semileptonic Bs decays: Ds - • Hadronic Ds decays: +, K*0K+, K+ K0, +,++-, K*0K*+ • Semileptonic Ds decays: e+, + • plepton> 2.5 GeV/c

  4. Efficiency • Improved by the reprocessing by 10-20%

  5. Relevant backgrounds • Combinatorial background estimated from data • Physical background: BDsDX, D  X • Discriminated using (p, pT) of the lepton and no. of tracks forming a good vertex with the lepton • Large experimental uncertainty • Reflections from D+ decays

  6. Physical background • Background branching ratio (from PDG): • P(bDsD0(X)) = (9.1  1.9  1.3  2.5) % • P(bDsD+(X)) = (4.0  1.6  0.7  1.2) % • P(bDsD(X),D X) = (1.3  0.3  0.3) % • Signal branching ratio (from PDG): • P(bBs) = (10.5  1.7) % • P(BsDs X) = (8.1  2.5) % •  P(bBs Ds X) = (0.85  0.3) % • B/S ratio: 1.5  0.7

  7. Physical background (cont’d) • In the last published analysis a different (and wrong) estimate of the background was given • P(bDs(*)D(*)+) = 5.0 % (in 1994 PDG) (only 2-body decays!) • B/S 2.6 lower! • In fact, the estimated ratio of background to signal in selected events was  0.1; now it is  0.3 (with the same selection)

  8. Physical background (cont’d) Signal Background Lepton transverse momentum Lepton momentum No. of tracks vertexing with the lepton

  9. Physical background (cont’d) • If lepton PT > 2 GeV/c   > 0.9 • else, if lepton P> 15 GeV/c   0.85 - 0.95 • else,  0.65 - 0.80 (if Ntracks<4) • or   0.35 - 0.65 (if Ntracks4) • B0 : Bs : B+ = 0.42 : 0.19 : 0.39 (from MC) • relative fractions varied by 25% for systematics

  10. Other backgrounds • Combinatorial background: estimated from the number of candidates and events fitted in the data (error used for systematics) • Reflection background: estimated from the Monte Carlo • Overall average purity  40%

  11. Decay length • Average bias from the Monte Carlo (30 m) • Correction factors to the error are evaluated from the pull (3-20% depending on the channel) • Mean error  250 m

  12. Momentum • E estimated from energy flow • Bias corrected as function of pBs • Error as a function of pBs(p  3 GeV/c)

  13. Proper time • The proper time error is  0.25 ps

  14. Proper time (cont’d) • Proper time distributions for background taken from Monte Carlo BDsD background

  15. Initial state tagging • Data and Monte Carlo are in good agreement • The average mistag on signal is (26.4  0.5) %(from MC)

  16. Data sample • 297 candidates are selected in the data

  17. Systematics • Physical background (varied by 50%) • Combinatorial background (varied by its statistical uncertainty) • Decay length resolution (varied by stat. uncert. on the error correction) • Momentum resolution (varied by 10%) • Mistag (varied by 10%)

  18. Conclusions • Good selection efficiency • Purity as a function of the lepton properties (necessary, given the “unexpectedly” high amount of BDsDX background) • Reasonable proper time resolution • The rest in the following presentation...

More Related