Neutron stars at JLAB and the Pb Radius Experiment

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Neutron stars at JLAB and the Pb Radius Experiment PREX uses parity violating electron scattering to accurately measure the neutron radius of 208 Pb. 208 Pb This has many implications for nuclear structure, astrophysics, atomic parity non-conservation, and low energy tests of the Standard Model. JLAB Users Group Meeting, June 2009 C. J. Horowitz, Indiana University

PREX and Related Physics Introduction: PREX exp. PREX and: JLAB Atomic PNC. Nuclear structure. Neutron stars. Radiative corrections to PREX and Qweak. Neutron star Atomic PNC 2

Parity Violation Isolates Neutrons In Standard Model Z 0 boson couples to the weak charge. Proton weak charge is small: Q p W = 1 4sin2 Θ W 0.05 Neutron weak charge is big: Q n W = 1 Weak interactions, at low Q 2, probe neutrons. Parity violating asymmetry Apv is cross section difference for positive and negative helicity electrons A pv = dσ/dω + dσ/dω dσ/dω + + dσ/dω Apv from interference of photon and Z 0 exchange. In Born approximation A pv = G F Q 2 2πα 2 F W (Q 2 ) = F W (Q 2 ) F ch (Q 2 ) d 3 r sin(qr) ρ W (r) Qr PREX will measure Apv for 1.05 GeV electrons scattering from 208 Pb at 5 degrees to 3%. This gives neutron radius to 1% (±0.05 fm). Donnelly, Dubach, Sick first suggested using PV to measure neutrons.

Weak and E+M charge densities 208 Pb Relativistic mean field calculation showing point proton and neutron densities (dashed) and weak and electromagnetic charge densities (solid). ρ W (r) = Total weak charge of nucleus d 3 r [G n W (r r)ρ n (r ) + Qp W Q n W Q W = G p W (r r)ρ p (r )] d 3 rρ W (r) = N (1 4 sin 2 Θ W )Z

New 5 0 Septum being developed Increases the Figure of Merit HRS-L Septum Magnet HRS-R target collimator PREX Workshop Aug 08 R. Michaels Hall A

High Resolution Spectrometers Spectrometer Concept: Resolve Elastic 1 st excited state Pb 2.6 MeV Elastic detector Inelastic Left-Right symmetry to control transverse polarization systematic target Dipole Quad PREX Workshop Aug 08 R. Michaels Q Q

Systematic Error Challenges Small asymmetry: 500 ± 15 ppb High precision: δa pv /A pv ± 3% No backgrounds (not what you might think ---> spectrometers) 1% normalization (polarimetry). Analyzing power ~ 10 Apv. Need to measure and control transverse components of polarization. Need excellent control of helicity correlated beam properties. Hall A parity collaboration has completed a number of successful parity experiments.

PREX and Atomic Parity Nonconservation 208 Pb 8

Atomic Parity Nonconservation Atomic PNC depends on overlap of electrons with neutrons in nucleus. Cs experiment good to 0.3%. Not limited by R n but future 0.1% exp would need R n to 1% Measurement of Rn in 208 Pb constrains nuclear theory for Rn in other atomic PNC nuclei. Combine neutron radius from PV e scattering with an atomic PNC exp for best low energy test of standard model. Berkeley Yb exp. Recent Atomic PNC Progress: Improved atomic theory for Cs. First PNC results from Berkeley Yb experiment. Start of TRIUMF program for laser trapped radioactive Fr. KVI program on PNC in Ra+.

PREX and Nuclear 208 Pb Structure Experimental charge densities from electron scattering

Neutron Skin and Symmetry E 208 Pb has Z=82 protons and N=126 neutrons. Where do the N-Z=44 extra neutrons go? In the center of the nucleus? At the surface? Relevant microphysics: A pn pair in bound 3 S1 state has more attractive interaction than pp or nn pair in unbound 1 S0 state. The symmetry energy S(n) describes how E of nuclear matter rises when one goes away from N=Z. E(n, δ) E(n, δ = 0) + δ 2 S(n) δ = (N Z)/A PREX will constrain density dependance of sym. E, ds/dn. Symmetry E very important to extrapolate to neutron rich systems in astrophysics. 11

Pb Radius Measurement!!! Pressure forces neutrons out against surface tension. Large pressure gives large neutron radius. Pressure depends on derivative of energy with respect to density. Energy of neutron matter is E of nuc. matter plus symmetry energy. Rn-Rp (fm) for 208 Pb Alex Brown et al.! Neutron radius determines P of neutron matter at! 0.1 fm -3 and the density dependence of the symmetry energy ds/d!. Neutron minus proton rms radius of Pb versus pressure of pure neutron matter at!=0.1 fm -3.

PREX and Neutron Stars 208 Pb 13

Neutron Star Crust vs 208 Pb Neutron Skin Liquid/Solid Transition Density Neutron Star 208 Pb FP Liquid Solid TM1 Neutron star has solid crust (yellow) over liquid core (blue). Nucleus has neutron skin. Both neutron skin and NS crust are made out of neutron rich matter at similar densities. Common unknown is EOS at subnuclear densities. Thicker neutron skin in Pb means energy rises rapidly with density-> Quickly favors uniform phase. Thick skin in Pb->low transition density in star. J Piekarewicz, CJH

Neutron Star Quadrupole Moment and Gravitational Waves A solid crust can support an off axis mass quadrupole moment. Rapidly rotating NS quad. moment efficiently radiates gravitational waves. Very active ongoing/ future searches for continuous GW at LIGO, Virgo, Advanced LIGO... How big can the quad. moment be? This depends on the thickness and strength of the crust (before any mountain collapses under the extreme gravity of a NS). We have performed large scale molecular dynamics simulations of the crust breaking stress, including effects of defects, impurities, and grain boundaries... We find: neutron star crust is the strongest material known. It is 10 billion times stronger than steel. Very promising for GW searches. LIGO Hanford --- with Kai Kadau (LANL), PRL102, 191102 (2009) 15

Pb Radius vs Neutron Star Radius The 208 Pb radius constrains the pressure of neutron matter at subnuclear densities. The NS radius depends on the pressure at nuclear density and above. Central density of NS few to 10 x nuclear density. Important to have both low density and high density measurements to constrain density dependence of EOS from a possible phase transition. If Pb radius is relatively large: EOS at low density is stiff with high P. If NS radius is small than high density EOS soft. This softening of EOS with density could strongly suggest a transition to an exotic high density phase such as quark matter, strange matter, color superconductor J Piekarewicz, CJH

Measuring Neutron Star Radii Deduce surface area from luminosity, temperature from X-ray spectrum. Complications: Need distance (from parallax for nearby isolated NS...) Non-blackbody corrections from atmosphere models can depend on composition and B field. Curvature of space: measure combination of radius and mass. Proposed International X-ray Observatory (larger collecting area) can measure both R and mass. L " = 4#R 2 $ SB T 4 IXO could be an important machine to study dense QCD. 17

Radiative Corrections

γ-z Box Diagrams Z 0 + γ Z 0 + γ Z 0 Qw Qw Elastic Inelastic Elastic intermediate states are coherent, order Zα. Important for PREX (Pb has Z=82). Inelastic is order α/qw compared to tree level. Possibly important for Qweak exp on proton. Note inelastic involves weak transition form factor and not weak charge Qw!

Coulomb Distortions for PREX We sum elastic intermediate states to all orders in Zα by solving Dirac equ for e moving in coulomb V and weak axial A potentials. A G F ρ W (r) 10 ev V (r) 25MeV Right handed e sees V+A, left handed V-A A pv = [dσ/dω V +A dσ/dω V A ]/2dσ/dΩ Coulomb distortions reduce A pv by ~30%, but they are accurately calculated. --- With E.D. Cooper!

Inelastic γz box correc. for Qweak Not obviously big for PREX, but important for the Qweak experiment because of the small weak charge of the proton. We sum over excited nucleon states with a dispersion integral using a model that fits photo-absorption data. Two main contributions: Resonances ~2%, dominated by Delta. High E non resonant contribution that we evaluate using a generalized vector meson dominance model ~4%. For 1.16 GeV kinematics of Qweak we find a total correction of 5.7% to the parity violating asym. compared to the exp error goal of 2% (statistical). with M. Gorchtein, Phys. Rev. Let. 102, 091806

We don t want Qweak to be another NuTeV NuTeV is a beautiful Fermi Lab neutrino experiment that has proved difficult to interpret as a Standard Model test. Important to have more work on radiative corrections to Qweak involving excited nucleon intermediate states. This should be done soon. NuTeV Qweak

Pb Radius Experiment 208 Pb PREX uses parity violating electron scattering to accurately measure the neutron radius of 208 Pb. This has implications for nuclear structure, astrophysics, and atomic parity nonconservation. People: Coulomb distortions with E.D. Cooper. Correlations with J. Piekarewicz. Radiative corrections with M. Gorshtein. PREX spokespersons: Paul Souder, Krishna Kumar, Robert Michaels, and Guido Urciuoli. Exp. to run Spring 2010. Supported in part by DOE and State of Indiana. 23

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