Review of Experimental CP-Conserving Processes in Heavy Flavour Physics
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Review of Experimental CP-Conserving Processes in Heavy Flavour Physics
J. Michael RoneyUniversity of Victoria
(BABAR Member)
Chateau de Blois17 July 2010
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J.M. Roney - non-CP Heavy Flavour2
standard model's flavour sector
~two dozen fundamental SM parameters
• Couplings of EW and strong interactions
• Weak mixing angle, Z boson mass
• Masses of quarks and leptons
• Matrix characterizing the mixing of weak and mass eigenstates of quarks and, recently in extended SM, leptons
• Higgs mass, strong-CP angle
Heavy flavour sector primarily touches on the Cabibbo-Kobayashi-Maskawa (CKM) matrix
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J.M. Roney - non-CP Heavy Flavour3
CKM Matrix
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d' s' b'( ) =
Vud Vus Vub
Vcd Vcs Vcb
Vtd Vts Vtb
⎛
⎝
⎜ ⎜ ⎜
⎞
⎠
⎟ ⎟ ⎟
d
s
b
⎛
⎝
⎜ ⎜ ⎜
⎞
⎠
⎟ ⎟ ⎟
In SM weak charged transitions mix quarks of different generations Encoded in unitary CKM matrix
Unitarity 4 independent parameters, one of whichis the complex phase and sole source of CP violation in SM
Wolfenstein parameterisation:CKM
V
€
=1− λ2 /2 λ Aλ3(ρ − iη )
−λ 1− λ2 /2 Aλ2
Aλ3(1− ρ − iη ) −Aλ2 1
⎛
⎝
⎜ ⎜ ⎜
⎞
⎠
⎟ ⎟ ⎟+ O(λ4 )
qi
W -
qjGFVij
quark transition
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CKM Unitarity TrianglePhysics beyond the SM signaled by
breakdown of unitarity of CKM matrix
€
λ2 =Vus
2
Vud
2+ Vus
2 ; A2λ4 =Vcb
2
Vud
2+ Vus
2 ; ρ + iη = −VudVub
*
VcdVcb*
* * * 0ud ub cd cb td tbV V V V V V
*
* *
*
*
* *
*
arg arg
arg arg
tb cd cb
ud tb
ud tb
td
ub td
ub tss
cd cb cs cb
V V VV
V VV V
V V
V V
V
V V
V
Area of Δ~CP violation
Wolfenstein parameterisation defined to hold to all orders in ~0.2 l and rephasing invariant
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CKM experimental programme
•Make as many precision measurements as possible that overconstrain the four CKM parameters (A, λ, ρ,η)
•New Physics would be revealed in discrepancies between measurements •Generally requires non-perturbative QCD input to convert measurements to a SM CKM interpretation
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Programme: Over constrain CKM with broad set of measurements
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Vud superallowed β decays
Vus K l 3 → πl ν ;K l 2 → l ν /
εK CPV in K0
Vub b → ul ν ; B → (π /ρ)l ν ;B → τν
Vcb B → D(*)l ν
Δmd Bd0 - Bd
0 mixing
Δms Bs0 - Bs
0 mixing
β B0 → J /ψ K(*)
α B0 → ππ/πρ/ρρ
γ B0 → D(*)K(*) Vtd /Vts b → dγ /b → sγ;Bd
0 & Bs0mixing
Quantity Sample Measurement(s)
Although we probe the charged weak interaction, we need input from strong interaction calculations, which are difficult and often need data
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J.M. Roney - non-CP Heavy Flavour7
Graphically present results as overconstrained Unitarity Triangle
CKM Fitter group uses frequentist framework UTFit uses Bayesian framework
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ρ =0.139−0.023+0.027 η = 0.342−0.015
+0.016
€
ρ =0.130 ± 0.020 η = 0.355 ± 0.013
levels@95%Prob
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Major experiments providing flavour data… so far
BESIII @ BEBC II
KLOE, BNL-E865, KTeV, ISTRA+ and NA48
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Related Parallel Session talks
Semi-leptonic and Leptonic B Decays at B Factories - Elisabetta Barberio (Melbourne)
Recent B Physics Results from the Tevatron - Karen Gibson (Case Western)
Evidence for Significant Matter-Antimatter Asymmetry at DZero - Derek Strom (UIC)
Recent Charm Physics Results from e+e- B Factories - Rolf Andreassen (Cincinnati)
Recent Quarkonium Results from the e+e- B Factories - Simone Stracka (Milan)
Recent Tau Decay Results at B Factories - Kiyoshi Hayasaka (Nagoya)
Recent Results from CLEO - David Cassel (Cornell)
Single Top and V_tb at the Tevatron - Reinhard Schwienhorst (Michigan State)
Constraints on Quark and Neutrino 4th Generation SM Mixing Matrix - Heiko Lacker (Berlin)
Highlights of Flavour Violation in the Presence of a 4th Generation - Tillmann Heidsieck (Munich)
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Sample of recent measurements
•CP violating measurements will be discussed in the next presentation
•Here I'll address a few recent CP-conserving heavy flavour measurements
• |Vub| from Semileptonic B decays
• B leptonic decays
• |Vus| measurements
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|Vub| from Semileptonic B Decays
measurements based on decays with large branching fractions
Two experimental approaches:• Inclusive b→u l ν• Weak Quark decay + QCD
• Exclusive B→Xu l ν• QCD handled via Form factors with non-
perturbative input from e.g. lattice QCD
Address experimental issues, such as charm background, differently and have different QCD correction issues
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Example: recent BaBar result on untagged
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B → πl ν and B → ρl ν
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mES = E beam2 − (Σpi)
2
ΔE = ΣE i − E beam
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Determine |Vub| from simultaneous fit to calculated (lattice QCD) and measured values of partial decay rate as function of q2
€
Vub from B → πl ν(BABAR arXiv:1005.3288)
Latest BABAR measured q2 spectrum yields a value of:
Total error has similar contributions from lattice and experimental uncertainties
€
Vub = (2.95 ± 0.31) ×10−3
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€
Vub comparisons
Difference is a problem and perhaps should be identified as an unattributed uncertainty•work of multiple experiments, multiple theoretical groups.•exclusive result relies on non-perturbative normalization input•inclusive result uses mb, non-perturbative extrapolations and perturbative corrections
€
B → πl ν (2.95 ± 0.31) ×10-3
b → ul ν (4.37 ± 0.39) ×10-3
⎫ ⎬ ⎭
2.7σLatest combined fit to data,lattice
Inclusive, PDG2010 average:
UTFit 3.48±0.16 (ICHEP 2008)
CKMFitter 3.51±0.150.16 (Beauty 2009)
Predictions fromCKM fits:
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Leptonic Decays
Remarkably simple pseudo-scalar (spin = 0, Parity is negative) decays carry information about CKM elements, but come with a 'decay constant' factor which accounts for the strong interaction component • B→τν rate of decay α (fB|Vub|)2
• Ds→τν or Ds→μν rate α (fDs|Vcs|)2
• K→μν rate α (fK|Vus|)2
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Leptonic decaysParticularly interesting because some New
Physics theories have charged Higgs which contributed to the observed decay rate, e.g.
• Additional tree level contribution from a charged Higgs
• It does not suffer from helicity suppression, but gets the same ml dependence from Yukawa coupling
• Branching fraction theoretical expression depends on the NP model
+ W+b
u
l+
nℓ
B+
H+b
u
l+
nℓ
B+
W. S. Hou, Phys. Rev. D 48 (1993) 2342.
A.G. Akeroyd and S.Recksiegel J.Phys.G29:2311-2317,2003
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B+→τ+ντ Experimental method
Two approaches to reconstruct the ‘tag’, which are classified as hadronic or semileptonic
1. select signal candidate and check that remaining particles consistent with B decay (inclusive Btag reco)
2. Reconstruct Btag in exclusive modes and check if remaining particles consistent with Bsignal
Fully reconstructthis side: ‘tag’
Then look for signal this side: ‘signal’
ντ
τ+
ντ
νμ, νe
e+,μ+
X-
D(*)0
ϒ(4S)
B+B-
In reality at the ϒ(4S) the B+ and B- decay products all overlap
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Reconstruct event to select B-
events from background…
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....and look for excess of missing energy associated with the neutrino
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Phys. Rev. D 77, 011107(R) (2008)
Phys. Rev. D 81,051101(R) (2010)
Phys. Rev. Lett. 97, 261802 (2006)
arXiv:1006.4201[hep-ex]
BABAR Hadronic
BABAR Semi-leptonic
BELLE Semi-leptonic
BELLE Hadronic
B+→τ+ντ Results
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B+→τ+ντ Resultsworld average:B(B+→τ+ν)=(1.73±0.35)x10-4
~2.5σ higher than expected from CKM fit excluding B+→τ+ν
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B+→τ+ντ Resultssame conclusion from UTfit analysis Phys.Lett.B 687, 61 (2010)
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J.M. Roney - non-CP Heavy Flavour23
B+→τ+ντ Resultsthis is not easily attributed to problem with fB
because a 2.6σdifference persists when considering:
BBd is the ‘bag parameter’ and is calculatedon the lattice.
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Summary of leptonic B decay results
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Most precise CKM test is from the unitarity condition:
From the 1st row of the CKM matrix
• |Vub| is negligible in comparison to |Vud| ~1 and |Vus| ~0.2
• |Vud|=0.97425(22) is most precisely obtained from super-allowed nuclear beta decay
• |Vus| is most precisely obtained from Kaon decays
€
Vud
2+ Vus
2+ Vub
2=1
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|Vus| from kaons
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|Vus| from kaons
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Vus = 0.2254(13), Vus /Vud = 0.2312(13), Vud = 0.97425(22)
€
Fit with no CKM unitarity constraint:
€
Vus = 0.2253(9), Vud = 0.97425(22)
χ 2 /dof = 0.014 /1 (91%)
Fit with CKM unitarity constraint:
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Vus = 0.2254(6)
χ 2 /dof = 0.024 /2 (99%)
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Vus
2+ Vus
2+ Vus
2−1 = −0.0001(6)
this analysis fromAntonelli et al arXiv:1005.2323(hep-ph 2010)(uses fK/fπ= 1.193(6) )
KLOE, BNL-E865, KTeV, ISTRA+ and NA48
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|Vus| from inclusive tau decays to kaons:τ+→Xsντ
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|Vus| from inclusive tau decays to kaons:τ+→Xsντ
Belle and BABAR
measured many modeswith significantly higherprecision than previousworld averagesfrom LEP and CLEO.Measurements areconsistent with previousmeasurements, butslightly lower.
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€
€
Use δR00 = 0.240 ± 0.032 (Gamiz et al., 2007)
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Vus = 0.2151± 0.0026
|Vus| from inclusive tau decays to kaons:τ+→Xsντ
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|Vus| fromBABAR (arXiv:0912.0242)
€
τ−→ K -ν τ
€
K -ν τ
€
π -ν τ
€
e-ν τν e
€
μ-ν τν μ
Branching Ratios
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Vus = 0.2193 ± 0.0032
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fK =157 ± 2 MeV
E. Follana, et al, PRL 100, 062002 (2008).
lattice and experimental: similar contribution to errorValue within 1σ of exclusive |Vus| and within 2σ of unitarity
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← 1.8σ lower than
π → μν prediction
← 1.8σ lower than
K → μν prediction
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|Vus| from
€
B(τ − → K -ν τ ) /B(τ − → π -ν τ )
BABAR (arXiv:0912.0242)
Improve lattice error by taking ratio:
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Vus = 0.2255 ± 0.0024€
Using : fK / fπ =1.189 ± 0.007 MeV
E. Follana, et al, PRL 100, 062002 (2008)
Vud = 0.97425 (22)
Consistent with unitarity
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Summary and Prospects
• Flavour sector provides a means of probing physics beyond the SM at the precision frontier
• The SM describes the flavour data, but there are seen a few ‘tensions’ in the flavour sector requiring attention
• Looking forward to new data from LHCb and in the future SuperB and SuperKEKB