1. N. ILINA, V. GAVRILOV (ITEP, Moscow)
Study of jet transverse structure using the second moment of ET radial distribution
N. ILINA, V. GAVRILOV (ITEP, Moscow)
O. KODOLOVA (SINP MSU)
RDMS Physics and DPG workshop
12/03/2009

2. Outline Introduction Samples Variables
Study of systematic shifts and uncertainties
Predictions of different generators (PYTHIA vs. HERWIG++)
Possibility to measure quark jets fraction
Summary
RDMS Physics and DPG workshop
12/03/2009

3. Introduction The study is important for CMS commissioning
Validation of CMSSW: detector modelling
Validation of generators
The jet shape study could provide the tool for quark-gluon jets separation
The internal structure of a jet is expected to depend on the type of parton creating the jet (light-quark or gluon) and ET of the jet
the study of jet shapes can help to test the models of underlying events and parton cascades
S.D.Ellis, Z.Kunszt and D.E. Soper, Phys.Rev.Lett. 69, 3615 (1992);
J.Pumplin, Phys.Rev. D 44, 7(1991)
RDMS Physics and DPG workshop
12/03/2009

4. pp collisions at TeV , 10 pb-1
Samples.
pp collisions at TeV , 10 pb-1
IC5 Algorithm
L2L3 jet energy corrections
JetPlusTrack method
HERWIG++ Summer08 samples:
(CMSSW2.2.1 for analysis):
PYTHIA generator level (CSA08):
(CMSSW for analysis)
All distributions in AN at calorimeter level
to measure detector based systematics
to compare predictions on generator level
from PYTHIA and HERWIG
to compare predictions
from PYTHIA and HERWIG on generator level
RDMS Physics and DPG workshop
12/03/2009

5. Variables at CMS: dR2, dj2, dh2
The integrated jet shapes (CDF definition) – the average fraction of the jet transverse momentum that lies inside a cone of radius r concentric to the jet cone (was used in CMS Note 2008/024).
We suggest CMS to use variables - second moment of ET radial distribution - which doesn’t depend on any inner radius:
Variables sensitive to internal jets structure and detector effects
RDMS Physics and DPG workshop
12/03/2009

6. dR2 vs PT for matched jets at |h| < 1
Particle level
Calorimetric level
gen
corr
All jets become narrower when their transverse momentum increases
Particle level jets and calorimetric jets have a similar behavior
RDMS Physics and DPG workshop
12/03/2009

7. dR2 vs PT for different h-regions
Quark jets
Gluon jets
RDMS Physics and DPG workshop
12/03/2009

8. Detector related systematic shifts and uncertainties
RDMS Physics and DPG workshop
12/03/2009

9. The sources of detector based systematic shifts for dR2
Sources of systematics:
strong magnetic field
non linear calorimeter response to hadrons
hadron shower and calorimeter tower transversal sizes
jet angular resolution
jet energy scale and jet energy resolution
RDMS Physics and DPG workshop
12/03/2009

10. Systematic shift due to magnetic field
Particle level
Calorimetric level
Jets do not have large difference in size in η
and j directions on particle level
On calorimetric level jets become oblong in j direction
due to influence of magnetic field
RDMS Physics and DPG workshop
12/03/2009

11. Jet shapes with tracks Particle level Calorimetric level
Magnetic field doesn’t affect dR2tracks
Tracker jet shapes:
RDMS Physics and DPG workshop
12/03/2009

12. Systematic shift due to jet energy scale (MC L2L3 jet energy corrections)
The systematic shift due to jet energy scale can be calculated from the difference of tracker jet shapes δR2tracks(PTcal) and δR2tracks(PTgen)
RDMS Physics and DPG workshop
12/03/2009

13. Systematic shift due to jet energy scale (JetPlusTrack jet energy scale)
JetPlusTrack Algorithm
There is no dependence on jet type (quark ar gluon) for JetPlusTrack algorithm
RDMS Physics and DPG workshop
12/03/2009

14. Predictions from different generators PYTHIA vs. HERWIG++
RDMS Physics and DPG workshop
12/03/2009

15. dR2(PT) : HERWIG++ vs. PYTHIA6 Particle level
All matched jets
Quark jets
Gluon jets
The main difference between PYTHIA and HERWIG++ samples is in gluon jet shape
RDMS Physics and DPG workshop
12/03/2009

16. dR2(PT) : Theoretical and detector systematics
gen
Very preliminary!
RDMS Physics and DPG workshop
12/03/2009

17. dR2(PT) for different h-regions. Herwig++ predictions
gen
Jet shapes for all jets(black lines) depend on h while jet shapes for gluon/quark jets are invariant. There are different quark/gluon jets fraction in the rapidity regions
RDMS Physics and DPG workshop
12/03/2009

18. Measurement of quark-jets fraction from jet shapes
RDMS Physics and DPG workshop
12/03/2009

19. Measurement of quark-jets fraction
Fraction of quark jets was calculated in 2 ways:
I. From ET spectrum:
II. From jet shapes:
The calculation of quark jets fraction from jet shapes can be applied for data
RDMS Physics and DPG workshop
12/03/2009

20. q-jets fraction from PT spectrum and from jet shapes
Particle level
gen
Fraction of quark jets determined from jets spectrum is in good agreement with q-jets fraction determined from δR2 distributions
Fraction of quark jets rises with increasing transverse momentum
RDMS Physics and DPG workshop
12/03/2009

21. q-jets fraction for different h-regions PYTHIA vs. HERWIG++
gen
HERWIG++ and PYTHIA predict the similar quark jets fraction
RDMS Physics and DPG workshop
12/03/2009

22. Summary
The details of the jet shapes study is in
RDMS Physics and DPG workshop
12/03/2009

23. Summary Pre-approval of the study is scheduled on April, 14 12/03/2009
RDMS Physics and DPG workshop
12/03/2009

24. Back-up
RDMS Physics and DPG workshop
12/03/2009

25. PT spectra for matched jets at |h| < 1
Calorimetric level
Particle level
For 1 sample: JetEt150/s156
RDMS Physics and DPG workshop
12/03/2009

26. Fraction of q-jets for different h-regions
Particle level
Calorimetric level
In central rapidity region the fraction of quark jets is smaller
It rises in endcap and forward regions (in endcap jets becomes narrower)
RDMS Physics and DPG workshop
12/03/2009

27. Statistical advantage of new CMS variable
Integrated jet shape 1-y(0.2) (CDF variable)
dR2 (CMS variable)
Sensibility = D/sstat, where D = ; sstat =
For 500 GeV < Pt < 550 GeV:
D/sstat(1-y(0.2) =
D/sstat (dR2) =
So dR2 gives ~2 times better accuracy than y(0.2)
with the same number of events
RDMS Physics and DPG workshop
12/03/2009