Presentation is loading. Please wait.

Presentation is loading. Please wait.

Peter Fauland (for the LHCb collaboration) The sensitivity for the B S - mixing phase  S at LHCb.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Peter Fauland (for the LHCb collaboration) The sensitivity for the B S - mixing phase  S at LHCb."— Presentation transcript:

1 Peter Fauland (for the LHCb collaboration) The sensitivity for the B S - mixing phase  S at LHCb

2 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 2/22   s in the standard model  Measuring  s at LHCb  The LHCb MC simulation  Results on the sensitivity to  s (using Toy MC) Outline

3 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 3/22  s in the standard model Mixing : Standard model box diagrams (  F=2 transitions) If only SM box diagrams Mixing phase  and If NP contributions in B s mixing

4 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 4/22  s in the standard model Wolfenstein parameterization of the CKM matrix ( V us, A, ,  ) Thus  in the B s system corresponds to  in the B d system (therefore  is also referred to as  s ) B d -system well measured, but B s -system (  M s,  s, , |p/q|) not fully explored  LHCb will have a large statistics

5 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 5/22 CP asymmetry The time dependent CP asymmetry allows us to measure  s. CP eigenstates with eigenvalues:  f =  1 CP : interference in mixing and decay (no direct CP) is dominated by a single weak phase  q  0 (with  q  0)

6 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 6/22 Measuring  s at LHCb The following B s -decays have been used to determine the LHCb sensitivity to  s : Thus : measure the B s mixing phase  s and see if it agrees with SM expectation from the box diagrams (check if  s  -2  = -2 2   -0.04) B s  J/  (  -  + )  (K + K - ) CP-odd and CP-even eigenstates B s  c (h - h + h - h + )  (K + K - ) CP-even eigenstate B s  J/  (  -  + )  (  ) CP-even eigenstate B s  J/  (  -  + )  (  +  -  0 (  )) CP-even eigenstate B s  D s (K + K -  - ) D s (K + K -  + ) CP-even eigenstate B s  D s (K + K -  - )  +  M s determination, wrong tag fraction, Control Channel

7 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 7/22 Angular analysis (CP-odd/CP-even separation) R T = 0  CP even R T = 0.5  maximum dilution ( but still some sensitivity to  s since odd and even contributions have different  tr distribution ) Measurements  R T  0.2 Complication for: Decay into two vector particles The angular distribution is used to separate odd and even components

8 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 8/22 The LHCb experiment LHCb under construction. It’s real! LHCb Single arm spectrometer with: good vertexing/tracking for reconstruction of the primary and B-decay vertex. good particle identification

9 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 9/22 The LHCb MC simulation The results in the next slides have been obtained with the LHCb Monte Carlo simulation. Detailed and realistic detector and material description Full pattern recognition, trigger simulation (also HLT), and offline event selection. Realistic detector inefficiencies, noise hits, and effects of events from the previous bunch crossings Geant simulated event

10 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 10/22 Results on the event selections Yield (10 3 /2 fb -1 ) B/S (fs)  mass (MeV/c 2 ) w tag (%)  tag (%) B s  J/  (  -  + )  (K + K - ) 1310.1236143357 B s  c (h - h + h - h + )  (K + K - ) 30.630123166 B s  J/  (  -  + )  (  ) 8.52.037343563 B s  D s (K + K -  - ) D s (K + K -  + ) 4.00.35663457 B s  D s (K + K -  - )  + 1200.440143163 The sensitivity to  s : B s  J/  : Large yield, but mixture of CP-odd and CP-even eigenstates. B s  J/  ( ’ ), B s  c  : Low yield, high background, but CP-even. B s  D s D s : Low yield, worse proper time resolution, but CP-even.

11 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 11/22 Results on the event selections BsBs ++ K+K+ K-K- DsDs PV  -- K+K+ K-K- DsDs BsBs K+K+ h-h- h+h+ K-K-  h-h- h+h+  cc

12 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 12/22 Sensitivity Studies using Toy MC As input the results from the full LHCb MC are used. The likelihood for the signal transitions is simultaneously optimized with the control sample (B s  D s  ). The tagging performance is assumed to be the same for the control and signal sample. The statistical uncertainty of control channel is thus included. Perform ~200 toy experiments, where each experiment represents 2fb -1 of data taking (10 7 s at 2  10 32 cm 2 s -1 ). The RMS of the  s distribution is given as the sensitivity. The CP parameters are extracted by performing a likelihood fit to the mass and proper time distributions (and to the transversity angle for B s  J/  ). Standard model values are used as input

13 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 13/22 Modeling the mass and  tr distributions Projection of the likelihood on mass distribution for B s  J/ . The mass peak is modeled by an Gaussian signal over an exponential background. Projection of the likelihood on the transversity angle distribution for B s  J/ . Blue=total, red dotted = CP-even, red dashed =CP-odd, black=background (is assumed to be independent on  tr.

14 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 14/22  s is 5  SM value Modeling the tagged proper time distributions Sensitivity to  s depends on D (tagging dilution factor) = 1-2w tag But  also sensitivity if we have untagged events (w tag =0.5, D=0) trough cos(  s ) term Include: Trigger and Selection bias on  Proper time resolution  s is 5  SM value Red solid line : tagged as initially Blue dashed : tagged as initially (Wrong tag fraction is included) For illustration only !

15 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 15/22 Modeling the tagged proper time distributions Projection of the likelihood on the proper time distribution Blue solid : Total Red dotted : Signal Black dashed : Background B s  c  (Standard model parameters) B s  J/  (Standard model parameters) B s  c  : better proper time resolution  wiggles in the signal are visible B s  J/  : higher background  flattens the wiggles Likelihood for the proper time distribution includes: acceptance function (full MC) per-event-error for the proper time (full MC) tagging performance exponential background function

16 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 16/22 Results on the sensitivity to  s Additional studies ongoing : The LHCb sensitivity for  s with 2 fb -1 Total LHCb sensitivity with 10 fb -1 : 0.01 rad = 0.6 degrees (but statistical uncertainty only) Channels 0.133 2.6 0.142 2.8 0.109 3.9 0.108 3.9 Combined sensitivity for pure CP eigenstates 0.059 13.2 0.023 86.8 Combined sensitivity for all CP eigenstates (  ) 0.021 100.0

17 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 17/22 The sensitivity for  s,  M s,  s /  s, R T, w tag with 2fb -1 Only Control sample used. Input to the likelihood fit

18 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 18/22 Results on the sensitivity to  s The effect of an improved or degraded proper time resolution (   ). And the effect of a larger B/S Dependence of the  s sensitivity on  s (It has been checked that the sensitivity does not depend on the sign of  s ) SM

19 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 19/22 Possible improvements for the sensitivity at LHCb Include the J/  e + e - events: expect ~20% increase of event yields Full angular analysis for B s  J/  Perform a combined fit with all signal channels Study the systematic uncertainty (extract proper time resolution from data) Optimize the use of the control sample (B s  D s  ) for the determination of the tagging performance of the signal samples (B s  J/ , B s  c , B s  J/  ( ’ ), B s  D s D s ) (define sub-samples with the similar tagging performance)

20 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 20/22 Conclusions The value of  s is not known very well ! The LHCb sensitivity for  s is 0.02 rad for 2 fb -1 Small dependence of the sensitivity on  s /  s and  s. After a few years of data LHCb will be able to measure also a SM  s. Already with a small data sample (~0.2 fb -1 ) we will have interesting results on  s. We aim for a  s result in 2008!

21 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 21/22 Thank you...

22 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 22/22 Results on the sensitivity to  s Dependence of the  s sensitivity on the CP-odd fraction (R T ). The world average is 0.167  0.041.  very sensitive to R T, but we still have a reasonable sensitivity if maximum dilution (i.e. R T =0.5) Dependence of the  s sensitivity on  s /  s. The world average is 0.14  0.06.  not very sensitive to  s /  s. nominal

23 Monday, October 30, 2006 DPF / JPS 2006, Honolulu, Hawaii Peter Fauland 23/22

Download ppt "Peter Fauland (for the LHCb collaboration) The sensitivity for the B S - mixing phase  S at LHCb."

Similar presentations

LHCb-Babar Meeting 8 April 2005. Paul Soler University of Glasgow and Rutherford Appleton Laboratory A first look at B s J/ in LHCb.

LHCb-Babar Meeting 8 April Paul Soler University of Glasgow and Rutherford Appleton Laboratory A first look at B s J/ in LHCb.
Measurement of  David Hutchcroft, University of Liverpool BEACH’06      

Measurement of  David Hutchcroft, University of Liverpool BEACH’06      
Measurements of the angle  : ,  (BaBar & Belle results) Georges Vasseur WIN`05, Delphi June 8, 2005.

Measurements of the angle  : ,  (BaBar & Belle results) Georges Vasseur WIN`05, Delphi June 8, 2005.
Prospect for  s measurement at LHC Alessia Satta on behalf of the LHCb collaboration + some Atlas and CMS results Physics at LHC, 3 rd october 2008.

Prospect for  s measurement at LHC Alessia Satta on behalf of the LHCb collaboration + some Atlas and CMS results Physics at LHC, 3 rd october 2008.
1/15 Sensitivity to  with B  D(KK  )K Decays CP Working Group Meeting - Thursday, 19 th April 2007 Introduction B  DK  Dalitz Analysis Summary.

1/15 Sensitivity to  with B  D(KK  )K Decays CP Working Group Meeting - Thursday, 19 th April 2007 Introduction B  DK  Dalitz Analysis Summary.
Title Gabriella Sciolla Massachusetts Institute of Technology Representing the BaBar Collaboration Beauty 2005 - Assisi, June 20-24, 2005 Searching for.

Title Gabriella Sciolla Massachusetts Institute of Technology Representing the BaBar Collaboration Beauty Assisi, June 20-24, 2005 Searching for.
1 Rare Decays of B Hadrons at CDF Matthew Jones October 3, 2005.

1 Rare Decays of B Hadrons at CDF Matthew Jones October 3, 2005.
ICFP 2005, Taiwan Colin Gay, Yale University B Mixing and Lifetimes from CDF Colin Gay, Yale University for the CDF II Collaboration.

ICFP 2005, Taiwan Colin Gay, Yale University B Mixing and Lifetimes from CDF Colin Gay, Yale University for the CDF II Collaboration.
1 D 0 -D 0 Mixing at BaBar Charm 2007 August, 2007 Abe Seiden University of California at Santa Cruz for The BaBar Collaboration.

1 D 0 -D 0 Mixing at BaBar Charm 2007 August, 2007 Abe Seiden University of California at Santa Cruz for The BaBar Collaboration.
16 May 2002Paul Dauncey - BaBar1 Measurements of CP asymmetries and branching fractions in B 0   +  ,  K +  ,  K + K  Paul Dauncey Imperial College,

16 May 2002Paul Dauncey - BaBar1 Measurements of CP asymmetries and branching fractions in B 0   +  ,  K +  ,  K + K  Paul Dauncey Imperial College,
1 D 0 -D 0 Mixing at BaBar Charm 2007 August, 2007 Abe Seiden University of California at Santa Cruz for The BaBar Collaboration.

1 D 0 -D 0 Mixing at BaBar Charm 2007 August, 2007 Abe Seiden University of California at Santa Cruz for The BaBar Collaboration.
Radiative LHCb Vanya BELYAEVVanya BELYAEV (NIKHEF/Amsterdam & ITEP/Moscow) Vanya BELYAEV On behalf of LHCb Collaboration.

Radiative LHCb Vanya BELYAEVVanya BELYAEV (NIKHEF/Amsterdam & ITEP/Moscow) Vanya BELYAEV On behalf of LHCb Collaboration.
22 July 2005Mauro Donega HEP20051 B s lifetimes in hadronic decays at CDF Mauro Donegà Université de Genève on behalf of the CDF collaboration.

22 July 2005Mauro Donega HEP20051 B s lifetimes in hadronic decays at CDF Mauro Donegà Université de Genève on behalf of the CDF collaboration.
Pakhlov Pavel (ITEP, Moscow) Why B physics is still interesting Belle detector Measurement of sin2  Rare B decays Future plans University of Lausanne.

Pakhlov Pavel (ITEP, Moscow) Why B physics is still interesting Belle detector Measurement of sin2  Rare B decays Future plans University of Lausanne.
1 B s  J/  update Lifetime Difference & Mixing phase Avdhesh Chandra for the CDF and DØ collaborations Beauty 2006 University of Oxford, UK.

1 B s  J/  update Lifetime Difference & Mixing phase Avdhesh Chandra for the CDF and DØ collaborations Beauty 2006 University of Oxford, UK.
Recent Charm Results From CLEO Searches for D 0 -D 0 mixing D 0 -> K 0 s  +  - D 0 ->K *+ l - Conclusions Alex Smith University of Minnesota.

Recent Charm Results From CLEO Searches for D 0 -D 0 mixing D 0 -> K 0 s  +  - D 0 ->K *+ l - Conclusions Alex Smith University of Minnesota.
1 B Physics at CDF Junji Naganoma University of Tsukuba “New Developments of Flavor Physics“ Workshop Tennomaru, Aichi, Japan.

1 B Physics at CDF Junji Naganoma University of Tsukuba “New Developments of Flavor Physics“ Workshop Tennomaru, Aichi, Japan.
Chris Barnes, Imperial CollegeWIN 2005 B mixing at DØ B mixing at DØ WIN 2005 Delphi, Greece Chris Barnes, Imperial College.

Chris Barnes, Imperial CollegeWIN 2005 B mixing at DØ B mixing at DØ WIN 2005 Delphi, Greece Chris Barnes, Imperial College.
B 0 s  J/   LHC review Nicolò Magini University and INFN, Firenze For the ATLAS, CMS and LHCb collaborations Oxford, 28 th September 2006 Beauty 2006.

B 0 s  J/   LHC review Nicolò Magini University and INFN, Firenze For the ATLAS, CMS and LHCb collaborations Oxford, 28 th September 2006 Beauty 2006.
The BaBarians are coming Neil Geddes Standard Model CP violation BaBar Sin2  The future.

The BaBarians are coming Neil Geddes Standard Model CP violation BaBar Sin2  The future.

Similar presentations

Ads by Google