1 besiii/cleo-c workshop 1/13/03 ian shipsey cleo-c & cesr-c: a new frontier in weak and strong...
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BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 1
CLEO-c & CESR-c: A New Frontier in Weak and Strong Interactions
Ian Shipsey, co-spokesperson CLEO CollaborationPurdue University
DoDo, DoK-+
K-
K+
+
The CLEO-c Physics Program Overview
The CLEO-c CollaborationCarleton, Carnegie Mellon,Cornell, Florida, George Mason, Illinois,Kansas, Northwestern, Minnesota, Pittsburgh, Puerto Rico, Purdue, Rochester, RPI, SMU, Syracuse,Vanderbilt, Wayne State
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 2
Flavor Physics: is in “the sin2 era” akin to precision Z. Over constrain CKM matrix with precision measurements. Limiting factor: non-pert. QCD.
CLEO-c : the context
Charm at threshold can provide the data to calibrate QCD techniques “CLEO-c/CESR”Charm at threshold can provide the data to calibrate QCD techniques “CLEO-c/CESR”
LHC may uncover strongly coupled sectors in the physics that lies beyond the Standard ModelThe LC will study them. Strongly-coupled field theories are an outstanding challenge to theoretical physics. Critical need for reliable theoretical techniques & detailed data to calibrate them.
This Decade
The Future
Example:The Lattice
Complete definition of pert & non. Pert.QCD. Maturedover last decade, can calculate to 1-5% B,D,,…
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CLEO-c Physics ProgramWhat do we need to measure?
•flavor physics: overcome the non pert. QCD roadblock
•
• precision charm abs. branching ratio measurements (CLEO-c)
•CLEO-c: precise measurements of quarkonia spectroscopy &decay provide essential data to calibrate theory.
•D-mixing, CPV, rare decays. + measure strong phases
CLEO-c helps build the tools to enable this decade’s flavor physics and the next decade’s new physics.
Abs D hadronicBr’s normalize B physics
Semileptonic decays: Vcs,Vcd,unitarity form factors
Leptonic decays : decay constants
Tests QCD techniques in c sector, apply to b sector Improved Vub, Vcb, Vtd & Vts
•Physics beyond the Standard Model:
•strong coupling in Physics beyond the Standard Model
Precision charm lifetimes
ImportantInput for the lattice
Exist (not CLEO-c) do not exist
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 4
Vub/Vub 15%lB
l
D
Vcd/Vcd 7%lD
Vcs/Vcs =16%l
B D
Vcb/Vcb 5%
Bd Bd
Vtd/Vtd =36%
Bs Bs
Vts/Vts 39% Vtb/Vtb 29%
Vus/Vus =1%
l Vud/Vud 0.1%
e
pn
t
b
W
Goal for the decade: high precision measurements of Vub, Vcb, Vts, Vtd, Vcs, Vcd, & associated phases. Over-constrain the “Unitarity Triangles”- Inconsistencies New physics !
Many experiments will contribute. Measurement of absolute charm branching ratiosat CLEO-c will enable precise 1st column unitarity test & new measurements at Bfactories/Tevatron to be translated into greatly improved CKM precision.
Precision Quark Flavor Physics
CKMMatrixCurrentStatus:
Nc Wcs
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Importance of measuring absolute charm leptonic branching ratios: fD & fDsVtd & Vts
22
ts
td
BB
BB
s
d
V
V
fB
fB
M
M
ss
dd
~5-7%
i1
1
i
2
3
2
1
108.820050.0
tdBB
d
V
MeV
fBpsM dd
Lattice predicts fB/fD & fBs/fDs with small errorsif precision measurements of fD & fDs existed (they do not)We could obtain precision estimates of fB & fBs and hence precision determinations of Vtd and Vts
Similarly fD/fDs checks fB/fBs
d
d
BB
BB
d
d
Bf
Bf
M
M )()(5.0
)(
1.2% ~15% (LQCD)(LP03)
~ 14%c
c
D
D
f
f
~ 100%c
c
D
D
f
f
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|f(q2)|2
|VCKM|2
I. Absolute magnitude & shape of form factors are a stringent test of theory. II. Absolute charm semileptonic rate gives direct measurements of V cd and Vcs. III Key input to precise Vub vital CKM cross check of sin2
b
c
u
d
HQET
l
l
1) Measure D form factor in Dl. Calibrate LQCD uncertainties .2) Extract Vub at BaBar/Belle using calibrated LQCD calc. of B form factor.3) But: need absolute Br(D l) and high quality d (D l)/dE neither exist
223K
2cs3
2F
2|)(qf|p|V|
24
G
q
d
d
B
D
Importance of absolute charm semileptonic decay rates..
~ 25%B
B
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3(47.4 1.4 2.0 2.1) 10cbV
The Importance of PrecisionCharm Absolute Branching Ratios I
Stat: 3.0% Sys 4.2% theory 4.4%Dominant Sys: slow, form factorsAs B Factory data sets grow, and theory improves
dB(DK)/dB(DK) dVcb/Vcb=1.2%
Vcb from zero recoil in B D*l+PRL 89 (2002) 081803PRD 67, 032001 (2003)
3(1) (43.1 1.3 1.8) 10cbF V
CLEO
CLEO as example
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 8
*+o
o +B
DB1
D
h
h
Understanding charm content of B decay (nc)
Precision Z bb and Z cc (Rb & Rc)
At LHC/LC H bb H cc
The importance of precisionabsolute Charm BRs II
HQET spin symmetry test
Test factorization with B DDs
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•CESR-c
•Being modified for
low energy operation:
•wigglers added for
transverse cooling Expected machineperformance withfull complementof wigglers
• Ebeam ~ 1.2 MeV at J/
s L (1032 cm-2 s-1)
3.1 GeV 1.5
3.77 GeV 3.0
4.1 GeV 3.6
CESRL(@Y(4S)= 1.3 x 1033
Unmodified CESR1 day scan of the :(1/29/02) L ~ 1 x 1030
J/J/
CESR-c
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CLEO-c Run Plan & Status2002: Prologue: Upsilons ~4 fb-1 at Y(1S),Y(2S),Y(3S) (combined) Spectroscopy, matrix element, ee, B hb
10-20 times the existing world’s data (Nov 2001-Nov 2002)
Fall 2004: (3770) – 3 fb-1 ((3770) DD) 30 million DD6 million tagged D decays BESIII assumes 5nb all following CLEO-c speakers will use 10 nb & 5nb
Fall 2005: MeV – 3 fb-1 1.5 million DsDs events, 0.3 million tagged Ds decays (480 x MARK III, 130 x BESII)
CLEO c
A 3 yearprogram
4140~S
2003: Installed 1 prototype wiggler spring ‘03 Took ~5 pb-1 at (3770), 3 pb-1 (2S) Installed ½ production wigglers summer’03
9/03-1/04 (3770) (2S,) continuum
54 pb-1 2.5 pb-1 4.4 pb-1
Install ½ production wigglers spring’04
Fall 2006: (3100), 1 fb-1 –1 Billion J/ decays
MACHINECONVERSION
exceededgoal
assumes ( (3770) 10 )DD nb
Will showthis data
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1.5 T 1.0T
93% of 4p/p = 0.35%
@1GeVdE/dx: 5.7%
@minI93% of 4E/E = 2% @1GeV
= 4% @100MeV
83% of 4% Kaon ID with
0.2% fake @0.9GeV
85% of 4For p>1 GeV
Trigger: Tracks & ShowersPipelinedLatency = 2.5s
Data Acquisition:Event size = 25kBThruput < 6MB/s
CLEO III Detector CLEO-c Detector
Minor modification:replaced silicon withlow mass inner drift chamber summer ‘03
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CLEO III Physics: Two Examples
Good agreement: between CLEO BaBar & Belle
1st new hadronic transition observed in system in 20 years
1st result (2001) DISCOVERY (2003):b1P→ 1S
M() GeV
Beam constrained Mass (GeV/c2)
CLEO III is well understood detector! hep-ex/0311043
MC DATA
HFAG
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Y(4S) event (2001) (3770) event (2003)
(3770) events: simpler than Y(4S) events
•The demands of doing physics in the 3-5 GeV range are easily met by the existing detector.
•BUT: B Factories : 400 fb-1 ~500M cc by 2005, what is the advantage of running at threshold?
•Charm events produced at threshold are extremely clean•Large , low multiplicity
•Pure initial state: no
fragmentation•Signal/Background is optimum at threshold
•Double tag events are pristine–These events are key to makingabsolute Br measurements
•Neutrino reconstruction is clean•Quantum coherence aids D mixing & CP violation studies
DoK-+ Do K+e-
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Tagging Technique, Tag Purity @ Threshold CLEO-c simulation
• (3770) DD s ~4140 DsDs Charm mesons have many large branching ratios (~1-15%) low multiplicity: high reconstruction efficiency
high net tagging efficiency ~20% !
D K tag. S/B ~5000/1 !
Ds (KK) tag. S/B ~100/1
Beam constrained mass
Anticipate 6M D tags 300K Ds tags:Anticipate 6M D tags 300K Ds tags:
MC MC
Logscale!
Logscale!
In 1 year At Each s
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Low background in hadronic tag modes
Measure absoluteBr (D X) with double tags Br = # of X / # of D tags
CLEO-c sets absolute scale for all heavy quark measurements
KD
tagD
MC
Decay s L Double PDG CLEOc fb-1 tags (B/B %) (B/B %)
D0 K-+ 3770 3 53,000 2.4 0.6D+ K- ++ 3770 3 60,000 7.2 0.7Ds 4140 3 6,000 25 1.9
Absolute Branching Ratios
50 pb-1 ~1,000 events x2 improvement (stat) on D+ K- ++ PDG dB/B
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0 0D K D K
DATA
DATA*5pb-1
(2003)
Single tags: CLEO-c DATA
Single tag are clean
Preliminary
*Before newinner driftChamber installed
*Beforenewinner driftchamberinstalled
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 17
,D K D K
DATA
DATA*5pb-1
(2003)
Double tags: CLEO-c DATA
Double tag events are clean
Preliminary
*Beforenewinner driftchamberinstalled
giving confidence in our MC simulations & estimates of precision
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• Measure absolute Br (Ds
• Fully reconstruct one D (tag)
• Require one additional charged track and no additional photonsDs
Vcs, (Vcd) known from unitarity to 0.1% (1.1%)
Ds tag
Reaction Energy(MeV) L fb-1 PDG CLEO-c
f Ds Ds+ 4140 3 17% 1.9%
f Ds Ds+ 4140 3 33% 1.6%
f D+ D+ 3770 3 UL 2.3%
|fD|2
|VCKM|2
•Compute MM2
•Peaks at zero for Ds+
decay.
Expect resolution of ~Mo
MC
fDs from Absolute Br(Ds
2 22( ) ( ) ( ) ( ) ( )tag tagM E D E P D P
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 19
Semileptonic Decays |VCKM|2 |f(q2)|2
U = Emiss - Pmiss
Assume 3 generation unitarity: for the first time measure complete set of charm PS PS & PS V absolute form factor magnitudes and slopes to a few% with almost no background in one experiment. Stringent test of theory!
TaggedEventsLowBkg!
D0 l
D0 Kl dp
d
p
CLEO-c MC
Lattice
dp
d
p
D0 lD0 l
CLEO-c MC
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Semileptonic Decays: DATA
DATA*5pb-1
(2003)
*Beforenewinner driftchamberinstalled
0 hadronic tagD
U = Emiss - PmissDoK+- Do K-e+
K+-
e+
K-
Preliminary
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eD:11
eKD:10
eKD:9
eD:8
eD:7
eKD:6
eKD:5
eD:4
eD:3
eKD:2
eKD:1
s
0*s
0s
0
0
_0*
_0
0
0
*0
0
0
10
20
30
40
50
60
70
80
90
100
1 2 3 4 5 6 7 8 9 10 11
Decay modes
Err
or (%
)
CLEO-c Impact semileptonic dB/B
CLEO-c
PDG
CLEO-c will make significant improvements in the precision with which each absolute charm semileptonic branching ratio is known
Even with 50 pb-1 already accumulated CLEO-c will improve on the PDG value of dB/B for every D+ and D0 exclusive semileptonic and inclusive branching ratio. and will have ~x10 the statistics of the DELCO DeX inclusive spectrum (important for B semileptonic decays studies).
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Determining Vcs and Vcd
If theory passes the test…..
combine semileptonic and leptonic decays eliminating V CKM
(D+ l(D+ lindependent of VcdTest rate predictions at ~4%
Test amplitudes at 2%Stringent test of theory!
(Dsl(Dslindependent of VcsTest rate predictions at ~ 4.5%
Use CLEO-c validated lattice to calc. B semileptonic formfactor, then B factories can use Blv for precise Vub
Vcs /Vcs = 1.6% (now: 16%) Vcd /Vcd = 1.7% (now: 7%)
eKD0
eD0I
II
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Unitarity Constraints
|Vud|2 + |Vus|2 + |Vub|2 = 1 ??With current values this test fails at ~2 (PDG2002)
|Vcd|2 + |Vcs|2 + |Vcb|2 = 1 ??CLEO –c: test to ~3% (if theory D K/lgood to few %)& 1st column: |Vud|2 + |Vcd|2 + |Vtd|2 = 1 ?? with similarprecision to 1st row
2 3
2 2 4 2 4
3 2
1( )
21
1 ( )2
(1 ) 1
CKM
A i
V i A A O
A i A
1
b
s
d
VVV
VVV
VVV
b
s
d
tbtstd
cbcscd
ubusud
'
'
'
Compare ratio of long sides to 1.3%Also major contributions to Vub, Vcb, Vtd, Vts.
|VubVcb*||VudVcd*|
|VusVcs*|
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 24
COMPARISON
0
5
10
15
20
25
30Er
ror (
%)
DfsDf
)KD(Br
)D(BrS
)KD(Br 0
PDG
Compare B factories & CLEO-cCompare B factories & CLEO-c
CLEO-c 3 fb-1
Statistics limited
BFactory 400 fb-1
Systematics & Background limited
M=M(M( GeV/c
CLEO: f DS : DS*DS with DS
bkgd
S/N~14
B Factory CLEO technique with improvements
CLEO-c %ErrorDS
MC
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 25
CLEO-c Probes of New Physics
D mix & DCPV suppressed in SM – all the more reason to measure themDD mixing x = m/ y =/2 (3770)DD(C = -1) exploit coherence, no DCSD. (4140) DD (C = +1)
rD=[(x2+y2)/2] < 0.01 @ 95%CL (KK, Kl,Kl)
•CP violating asymmetries• Sensitivity: Acp < 0.01• Unique:L=1,C=-1 CP tag one side, opposite side same CP CP=±1 (3770) CP=±1 = CPV
•CP eigenstate tag X flavor mode
K+K- DCP (3770) DCP K-+
Measures strong phase diff. CF/DCSD cos ~0.05. Crucial input for B factories Needed for in BDK
Gronau, Grossman,Rosner hep-ph/0103110
y’= ycos-xsin x’= xcos+ysin Rare charm decays. Sensitivity: 10-
6
CP Dalitz analyses ex: DKs may provide greater CPV reach
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and Spectroscopy
– Masses, spin fine structure
• Leptonic widths for S-states.– EM transition matrix elements
resonances complete~ 4 fb-1 total
• Uncover new forms of matter –gauge particles as constituents
– Glueballs G=|gg Hybrids H=|gqq
Probing QCD
Study fundamentalstates of the theory
J/ running fall 2006 109 J/
Confinement,Relativistic corrections
Wave function Tech: fB,K BK f D{s)
Form factors
Verify tools for strongly coupled theories Quantify accuracy for application to flavor physics
Rich calibration and testing groundfor theoretical techniques apply to flavor physics
The current lack of strong evidence for these states is a fundamental issue in QCD Requires detailed understanding of ordinary hadron spectrum in 1.5-2.5 GeV mass range.
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•Gluons carry color charge: should bind!
•CLEO-c 1st high statistics experiment with modern 4 detector covering 1.5-2.5 GeV mass range. •Radiative decays:ideal glue factory:
•(60 M J/X)
Gluonic Matter
X
cc̄
•But, like Jim Morrison, glueballs have been sighted too many times without confirmation.
fJ(2220)
Example: Narrow state in inclusive Exclusive:
corroborating checks:Anti-search in : /Search in (1S)
CLEO-c
Shown B(fJ(2220) K+ K-)= 3.10-5 Sensitivity 5 B(fJ(2220) K+ K-)= 10-6
Sensitivity B( J/X)~10-4
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• Crucial Validation of Lattice QCD: Lattice QCD will be able to calculate with accuracies of 1-2%. The CLEO-c decay constant and semileptonic data will provide a “golden,” & timely test. QCD & charmonium data provide additional benchmarks.
CLEO-c Physics Impact
Imagine a world Where we have theoreticalmastery of non-perturbative QCDat the 2% level
B Factories only ~2005
Assumes theory errors reducedby x2
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• Crucial Validation of Lattice QCD: Lattice QCD will be able to calculate with accuracies of 1-2%. The CLEO-c decay constant and semileptonic data will provide a “golden,” & timely test. QCD & charmonium data provide additional benchmarks. (E2 Snowmass WG)
CLEO-c Physics Impact
Imagine a world where we have theoreticalmastery of non-perturbative QCDat the 2% level
B Factories only ~2005
Assumes Theory Errors reducedby x2
Theoryerrors = 2%
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The potential to observe new forms of matter- glueballs& hybrids, and new physics D mixing/CPV/rare provides a discovery component to the program
• Knowledge of absolute charm branching fractions is now contributing significant errors to measurements involving beauty quarks. CLEO-c can also resolve this problem in a timely fashion
• Improved Knowledge of CKM elements, which is now not very good.
CLEO-c Physics Impact
Vcd Vcs Vcb Vub Vtd Vts
7% 16% 5% 15% 36% 39%
1.7% 1.6% 3% 5% 5% 5%B Factory/Tevartron
Data & CLEO-c
Lattice
Validation
CLEO-cdata andLQCD
PDG
PDG
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 31
The CLEO-c Program: Summary
• Powerful physics case• Precision flavor physics – finally • Nonperturbative QCD – finally• Probe for New Physics
•This suite of measurements can only be performed with the requisite precision at a facility operating at charm threshold
• Optimal timing• LQCD maturing• allows Flavor physics to reach•its full potential this decade• Beyond the SM in next decade
The most comprehensive& in depth study ofnon-perturbative QCD yetin particle physics
Direct: Vcs Vcd &tests QCD techniquesaids BABAR/Belle/CDF/D0/BTeV/LHC-bwith Vub,Vcb,Vtd,Vts
First results from (3770) data in next few months
BESIII/CLEO-c Workshop 1/13/03 Ian Shipsey 32
Thank-you for the warm welcome, the hospitality, and the discussions we will share over the next three days.
On behalf of the CLEO Collaboration:
Both BES and CLEO have a great particle physics tradition. We are delighted to be part of this workshop which is a wonderful opportunity to learn from each other as we both embark on our journey to a new frontier in our understanding of the weak and strong interactions