1. First CMS Results with LHC Beam
Toyoko Orimoto
California Institute of Technology
On behalf of the CMS Collaboration
Lake Louise Winter Institute
16-21 February 2009
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

2. Toyoko Orimoto, Caltech
The CMS Detector
EM calorimeter: ECAL
PbWO4 crystal calorimeter
High resolution
High granularity, >70k crystals
Barrel (EB) & Endcap (EE)
Hadronic calorimeter: HCAL
Brass & scintillator
Barrel (HB), Endcap (HE), Outer (HO)
Tracker
66M Si pixels & 10M Si strips
Superconducting Solenoid
Very large, 6m x 13m
3.8T, 1.6 GJ stored energy
Muon System
Barrel: Drift Tubes (DT)
Endcap: Cathode Strip Chambers (CSC)
Barrel & Endcap interleaved with Resistive Plate Chambers (RPC)
Pixels
Tracker
ECAL
HCAL
Solenoid
Muons
Compact, Modular
Weight: t
Diameter: 15m
Length: 21.6 m
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

3. Timeline: First LHC Beams
7-9 September
Single shots of beam 1 onto closed collimator 150m upstream of CMS (“beam splash” events)
10 September (Media Day!)
Beam 1 circulated in the morning, 3 turns within 1 hour!
Beam 2 circulated by 3:00pm, 300 turns by evening
11 September
RF system captures beam at evening (millions of orbits)
BEAM
Collimators
146m
CMS
Debris
Beam Splash Schematic
Beam 2, E=450 GeV
Beam 1, E=450 GeV
CMS
The Large Hadron Collider
19 September
Faulty electrical connection between dipole and quadrupole failed, resulting in massive helium loss, cryogenics and vacuum lost
Beam elements being removed and replaced/repaired
During all these activities, CMS triggered and recorded data
~40 hours of beam to CMS
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

4. Beam Splash Event Display
Single beam shots of 2*109 protons onto closed collimators
Hundreds of thousands of muons pass through CMS per event
HCAL energy
ECAL energy
Longitudinal views
BEAM
Debris
Transverse views
DT muon chamber hits
LHC Tunnel profile visible
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

5. Beam Splash: ECAL Energy
Correlation Between Energies
in Barrel HCAL and ECAL
~150 TeV in ECAL
& ~1000 TeV in HCAL
per splash event
ECAL Endcaps
Energy (GeV)
Enormous amount of energy deposited in calorimeters!
~200 TeV energy deposited in EB+EE
> 99% of ECAL channels fired
Beam (clockwise) came from plus side.
crystal index iy
crystal index iy
crystal index ix
crystal index ix
TOP
BOTTOM
ECAL Barrel
crystal index i
crystal index i
Energy (GeV)
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

6. Toyoko Orimoto, Caltech
Beam Halo Muons
Beam Halo: Muons outside of beam-pipe, arising from decays of pions created when off-axis protons scrape collimators or other beamline elements 
Endcap Muon Cathode Strip Chamber Hits from Beam Halo Events
Muon Endcap Layer -1
Muon Endcap Layer -2
Muon Endcap Layer -3
Muon Endcap Layer -4
LHC Tunnel Profile
A useful tool for alignment and time synchronization
BEAM
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

7. Toyoko Orimoto, Caltech
Beam Halo Muons
1 muon
3 muons
Reconstructed Tracks
Endcap muon chambers
Three muons are reconstructed in the Cathode Strip Chambers (CSC's). The chambers with hits are shown as trapezoidal volumes in white, with yellow strips running in the radial direction, and purple wires running in the azimuthal direction. The long blue lines threading several chambers represent muon trajectories reconstructed offline. One line appears to be bent due to multiple scattering of the muon in the calorimeter.
This particular beam halo / beam gas event is unusual in having three reconstructed muons; most events have one.
Barrel muon drift tubes
Endcap muon chambers
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech 7

8. Halo and Cosmic Muon Angles
Angle of Muon Tracks wrt Beam Line
beam ON data =
beam halo MC
+ cosmic ray data
The normalization of the blue and black histograms are not based on any calculation; they are meant to guide the eye.
Beam halo muons to make a small angle
Cosmic Ray muons pass through the CSCs at a more oblique angle
Beam-on distribution consists of two pieces, one resembling cosmic rays and the other matching the beam halo simulation.
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

9. Beam Halo Before and After RF Capture
First RF capture of beam
Beam Halo Rates in Muon Endcaps
Muon Endcap (CSC) halo trigger rate in the minus endcap vs time.
First successful capture lasted for 10 min and ended with beam abort
HCAL Endcap Peak Energy Location & Amp
time h:m
Before
After
HCAL Endcap Energy
Before, high rate of energy deposition near beamline.
After, beam is cleaner, depositing less energy in HCAL endcap.
This plot shows the CSC halo trigger rate in the MINUS endcap as a function of time. The yellowish band indicates the first successful RF capture of the LHC beam (beam 2) which lasted about 10min (and ended with the first automatic beam abort). One sees rate jumps preceding this due to earlier capture attempts. These rates are defined by averaging over a 10 s interval.
Sectors 1 and 6 are mostly horizontal on the inside part of the ring
Y (cm)
Y (cm)
X (cm)
X (cm)
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech 9

10. CMS Performance with Cosmics
CRAFT: Cosmic Run at Full Tesla
~300 M cosmic events collected
Field at 3.8T operated for ~1 month
Participation from all subsystems
Detector performance studies as well as detailed cosmics studies ongoing
 Momentum
Data vs MC
ECAL dE/dx:
Experimental data vs Expected stopping power for PbWO4
collision loss
brem radiation
p (GeV/c)
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

11. CMS Performance with Cosmics
Si Strip Tracker: Signal to Noise
/ndof After Tracker Alignment
S/N = ~30
Excellent eff > 99%
S/N
/ndof
Pixel & Strip Tracker Alignment: Mean of Residuals
Pixel Barrel
RMS 47m
Strip Inner Barrel
RMS
26m
S/N ~30
Excellent eff > 99%
Using 4M tracks for alignment and 1M for validation
“Unaligned” is the nominal geometry
“CRUZET” is the geometry obtained from the B=0T runs using the Hits and Impact Point method and survey constraints
“CRAFTHIP” is the geometry obtained from the Hits and Impact Point algorithm applied to CRAFT data, including survey constraints
“CRAFTMP” is the geometry obtained from the Millepede algorithm applied to CRAFT data
Mean of residual distributions (cm)
Sensitive to module displacements
Only modules with >30 hits considered
TIB 96%, TID 98%, TOB 98%, TEC 94%
HIP algo: TIB RMS = 26m TOB RMS = 28m
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

12. Toyoko Orimoto, Caltech
CMS Detector Status
Since beginning of September 2008
All installed CMS sub-detectors in global readout routinely
All triggers operational
Stability of running with all CMS components proven
LHC clock and orbit signals tested
Synchronization to few ns or better
Have continued global data-taking with cosmics
CRAFT: Cosmic Run at Full Tesla
Detector opening started Nov 17th
Interventions/repairs for problematic channels
Installation of Preshower detector
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech

13. Toyoko Orimoto, Caltech
Conclusions
After many years of design & construction, CMS is commissioned and has collected first data with LHC
Detector performance proven with beam splash, beam halo, as well as cosmics with and without B field.
Expect more results, not just with single beam or cosmics, but with collisions!
First CMS Results with LHC Beam
Toyoko Orimoto, Caltech