Download - Nuclear Physics at Jefferson Lab Part II
Nuclear Physics at Jefferson LabPart II
R. D. McKeownJefferson LabCollege of William and Mary
Taiwan Summer SchoolJune 29, 2011
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• Strange Quarks
• Standard Model Tests
• Dark Matter?
Outline
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Strange Quarks in the Nucleon
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• Strange quarks-antiquarks virtual pairs produced by gluons
• Contribution to proton’s magnetism - (Stern’s discovery)?- QCD analog of Lamb shift in atoms
• Study using small (few parts per million) left-right difference in electron-proton force
challenging experiments!
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Strange Quarks in the Nucleon
Mass:
u u
dp
uudu
su
s
valence
sea
proton
4.0)(ˆ
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NdduumNNssmN sp-N scattering
Spin:
1.01.010.020.0
ssdu
gq JLsdu 21
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Polarized deep-inelastic scattering
HERMES semi-inclusive
n-p elastic scattering
09.015.0 s
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Electroweak charged fermion couplings
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Weak Charges
• QWp = 1 – 4 sin2 qW ~ 0.071
• QWn = -1
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Neutral weak form factors•Electromagnetic interaction
•Neutral weak interaction
g
p
Z0
p
GEg,p, GM
g,p GEZ,p, GM
Z,p
GAZ,p
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Use Isospin Symmetry
pZM
nM
pMW
sM
pZM
nM
pMW
dM
pZM
pMW
uM
GGGG
GGGG
GGG
,,,2
,,,2
,,2
)sin41(
)sin42(
)sin43(
gg
gg
g
q
q
q
(p n) = (u d)
For vector form factors theoretical CSB estimates indicate < 1% violations (unobservable with currently anticipated uncertainties)(Miller PRC 57, 1492 (1998) Lewis and Mobed, PRD 59, 073002(1999)
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Parity-violating electron scatteringPolarized electrons on unpolarized target
For a proton: (Cahn & Gilman 1978)
LR
LRA
g Z0
g 2
Forward angles Backward angles
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(VMD)
l Soliton, NJL, …l Dispersion Integralsl Lattice QCD
Theoretical Approaches
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Theoretical predictions for ms
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SAMPLE ExperimentPolarizedInjector
WienFilter
AcceleratorE = 125 MeV600 pulses/sIpk = 3 mAIave = 44 mAPB = 36%
Energy
BeamCurrent
Fast phase shift(energy) feedback
K11
Beam currentfeedback
SAMPLEDetector
Lumi
Position,Angle,Charge
Halo
MollerPolarimeter
Beam positionfeedback
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Experimental procedure
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
Positive Helicity Negative Helicity 60 Hz
Random (New)Sequence
ComplementSequence
Pulse Pair
A Y YY Y
MeasuredPositive Negative
Positive Negative
• Asymmetry between pulses separated by 1/60 sremove effects due to 60 Hz• Rapid helicity reversal reduce effects of long-term drifts• Slow helicity reversal remove helicity-correlated electronics effects
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GMs(Q2=0.1) =
0.37 +- 0.20 +- 0.26 +- 0.07
SAMPLE result
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ms Theory and Experiment
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Other Experiments
HAPPEX @ JLAB
A4 @ Mainz
G0 @ JLAB
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Global Analysis
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• Nucleon models continue to struggle, with some indication that higher mass poles are important
• Precise lattice QCD - motivated prediction:
(Leinweber, et al., PRL 97, 022001 (2006)
• New unquenched lattice QCD result:
Doi, et al., arXiv:0903.3232
Theory Update
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HAPPEX-III Results
A(Gs=0) = -24.158 ppm ± 0.663 ppm Gs
E + 0.52 GsM = 0.005 ± 0.010(stat) ± 0.004(syst) ± 0.008(FF)
APV = -23.742 0.776 (stat) 0.353 (syst) ppm
preliminary
preliminary
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Measuring the Neutron “Skin” in the Pb Nucleus
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crust
Neutron Star Lead Nucleus
skin
10 km
10 fm
• Parity violating electron scattering• Sensitive to neutron distribution• First clean measurement• Relevant to neutron star physics• Currently running in Hall A
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Lead (208Pb) Radius Experiment : PREXElastic Scattering Parity-Violating Asymmetry
Z0 : Clean Probe Couples Mainly to Neutrons
Applications : Nuclear Physics, Neutron Stars, Atomic Parity, Heavy Ion Collisions
• The Lead (208Pb) Radius Experiment (PREX) determines the neutron radius to be larger than the proton radius by +0.35 fm (+0.15, -0.17).
• This result represents model-independent confirmation of the existence of a neutron skin, with relevance for neutron star calculations.
• Plans for follow-up experiment to reduce uncertainties by factor of 3. This can quantitatively pin down the symmetry energy, an important contribution to the nuclear equation of state.
A neutron skin of 0.2 fm or more has implications for our understanding of neutron stars and their ultimate fate
Rel. mean field
Nonrel. skyrme
PREXPREX data
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Running of the Weak Coupling
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Global Fits
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PV electron-quark couplingsGeneral Form:
Standard model:
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Qweak
Luminosity monitors
Luminosity monitors
scanner
Precise determination of the weak charge of the proton
Qw= -2(2C1u+C1d) =(1 – 4 sin2 qW)
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Qweak Overview
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Target cell
• 35 cm target cell, designed with CFD • Target tested and stable up to 160 mA. Sufficient reserve cooling power to easily reach 180 mA. Highest power LH2 target.
• When using 960Hz spin flip rate, the target density fluctuations (an unknown before commissioning) appear to be small compared to expected counting statistical uncertainty (per quartet) of ~220 ppm.
Qweak LH2 Cryotarget
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Accelerator Performance for Qweak
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Qweak Projection
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Radiative Correction Uncertainty
(Ramsey-Musolf)
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Constraints on Couplings
HAPPEx: H, HeG0 (forward): H,PVA4: HSAMPLE: H, Dprojection
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New combination of: Vector quark couplings C1q Also axial quark couplings C2q
PV Deep Inelastic Scattering
iii fff
For an isoscalar target like 2H, structure functions largely cancel in the ratio at high x
b(x)
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(2C2u C2d )uv dv
u d
a(x) =C1i Qi fi
+(x)i
Qi
2 fi+(x)
i
e-
N X
e-
Z* g*
y 1 E / E b(x) C2i Qi fi
(x)i
Qi
2 fi(x)
i
x xBjorken
At high x, APV becomes independent of x, W, with well-defined SM prediction for Q2 and y
Sensitive to new physics at the TeV scale
a(x) 3
10(2C1u C1d ) 1
2s
u d
6.0
APV GFQ2
2pa(x) Y (y) b(x)
0
1
at high x
a(x) and b(x) contain quark distribution
functions fi(x)
PVDIS: Only way to measure C2q
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SoLID Spectrometer
Baffles
GEM’s
Gas Cerenkov ShashlykCalorimeter
ANL design
JLab/UVA prototype
Babar Solenoid
International Collaborators:China (Gem’s)Italy (Gem’s)Germany (Moller pol.)
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Statistical Errors (%)
4 months at 11 GeV
2 months at 6.6 GeV
Error bar σA/A (%)shown at center of binsin Q2, x
Strategy: sub-1% precision over broad kinematic range for sensitive Standard Model test and detailed study of hadronic structure contributions
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Sensitivity: C1 and C2 Plots
Cs
PVDIS
Qweak PVDIS
World’s data
Precision Data
6 GeV
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SoLID: Comprehensive PVDIS Study
• Measure AD in NARROW bins of x, Q2 with 0.5% precision• Cover broad Q2 range for x in [0.3,0.6] to constrain HT• Search for CSV with x dependence of AD at high x• Use x>0.4, high Q2, and to measure a combination of the Ciq’s
Strategy: requires precise kinematics and broad range
x y Q2
New Physics no yes noCSV yes no no
Higher Twist yes no yes
2
23)1(11 x
QxAA CSVHT Fit data to:
C(x)=βHT/(1-x)3
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PV Møller Scattering
SLAC E158 result: APV = (-131 ± 14 ± 10) x 10-9
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E158 Result
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New JLab Experiment
Polarized Beam• Unprecedented polarized luminosity• unprecedented beam stabilityLiquid Hydrogen Target• 5 kW dissipated power (2 X Qweak)• computational fluid dynamicsToroidal Spectrometer• Novel 7 “hybrid coil” design• warm magnets, aggressive coolingIntegrating Detectors• build on Qweak and PREX• intricate support & shielding• radiation hardness and low noise
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Toroidal Spectrometer
Mollerse-p elastic
Separate Moller events from background
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Projected MOLLER Results
Projected systematic error: dA/A = 1%
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Systematic Error Estimate
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Future PV Program at Jlab
PV Moller Scattering:
• Custom Toroidal Spectrometer• 5kw LH Target
SOLID (PVDIS):• High Luminosity on LD2 and LH2 • Better than 1% errors for small bins• Large Q2 coverage• x-range 0.25-0.75• W2> 4 GeV2
44INT EIC Workshop, Nov. 2010
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Weak Mixing in the Standard Model
JLab Future
45INT EIC Workshop, Nov. 2010
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Beyond the Standard Model
INT EIC Workshop, Nov. 2010
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Kurylov, et al.
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Muon g-2
Momentum
Spin
e
SUSY?47INT EIC Workshop, Nov.
2010
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On the horizon: A New Muon g-2 Experiment at Fermilab
Update: Oct 2010: am(Expt – Thy) = 297 ± 81 x 10-11 3.6
BNL E821
2010 e+e- Thy
3.6
x10-11
Future Goals
Goal: 0.14 ppm
Expected Improvement
D. Hertzog
48INT EIC Workshop, Nov. 2010
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Cosmology and Dark Matter
R. D. McKeown June 15, 2010
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• Dark sector is new physics, beyond the standard model• Many direct searches for dark matter interacting with
sensitive detectors (hints, no established signal yet…)• Controversial evidence for
excess astrophysical positrons…
→ many predictions for new physics
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PAMELA Data on Cosmic Radiation
Va. Tech. Physics Colloquium, Dec. 3, 2010
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Surprising rise in e+ fraction
But not p
• Could indicate low mass A’ (MA’ < 1 GeV )
• Or local astrophysical origin??
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NEW! Confirmation from Fermi
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AMS-02 Launched May 16, 2011slide from Andrei Kounine
TeVPA 2010
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New Opportunity: Search for A’ at JLabSearch for new forces mediated
by ~100 MeV vector boson A’ with weak coupling to electrons:
Irrespective of astrophysical anomalies: • New ~GeV–scale force carriers are important category of physics beyond the SM• Fixed-target experiments @JLab (FEL + CEBAF) have unique capability to explore this!
53Va. Tech. Physics Colloquium, Dec. 3, 2010
g – 2 preferred!
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APEX in Hall A
• Uses existing equipment• Successful 2010 test run
(results soon!)
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HPS in Hall B• Forward, compact spectrometer/vertex detector identifies heavy photon candidates with invariant mass and decay length.
• EM Calorimeter provides fast trigger and electron ID.
• Small cross sections and high backgrounds demand large luminosities. HPS survives beam backgrounds by spreading them out maximally in time, capitalizing on 100% CEBAF duty cycle and employing high rate DAQ.
• All detectors are split above and below the beam to avoid the “wall of flame” from multiple Coulomb scattered primaries, bremsstrahlung, & degraded electrons.
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DarkLight at JLab FEL
100 MeV10 mA
Reconstruct all final stateparticles and achieve aninvariant mass resolutionof 1 MeV/c2 or betterover the range 10 to 100MeV/c2.
Toroidal magneticspectrometer with abending power of 0.05 to 0.16 T-m with a wirechamber tracker for theleptons, a radial TPC for proton detection and a scintillator for triggering.
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Jlab Future
• Clearly we have a exciting and growing program to search for new physicsbeyond the standard model.
• But we have a substantial program ofimportant experiments exploring QCD
- confinement mechanism- nucleon tomography
• And there are prospects for a future newfacility: Electron Ion Collider (EIC)
One more lecture…
