PV Electron Scattering

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Presentation transcript:

PV Electron Scattering Coherent Neutrino and PV Electron Scattering Bill Donnelly MIT DNP 2013 TWD 1

Outline: Overview of PV electron scattering Deviations from the “standard” coherent elastic PV asymmetry: Isospin mixing; proton/neutron distributions Strangeness NC neutrino scattering Relationships between coherent elastic PV electron and neutrino scattering Summary Talk prepared with assistance from Oscar Moreno. TWD

PV electron scattering studies: Based on PV electron scattering studies: TWD, J. Dubach and I. Sick, A503 (1989) 589 [DDS] O. Moreno et al., Nucl. Phys. A828 (2009) 306 O. Moreno and TWD, PRC89 (2014) 1 weak neutral current studies: TWD and R. D. Peccei, Phys. Reports 50 (1979) 1 M. J. Musolf et al., Phys. Reports 239 (1994) 1 and coherent neutrino scattering: TWD and J. D. Walecka, Nucl. Phys. A274 (1976) 368 TWD, Los Alamos Report, LA-9358-C (1981) TWD, Prog. Part. Nucl. Phys. 13 (1985) 183 TWD 3

PV electron scattering: TWD

PV electron scattering: Same hadronic vertex for neutrino scattering TWD

TWD

magnetic EM multipoles Coulomb, electric and magnetic EM multipoles WNC multipoles (with carets) Axial-vector multipoles; the rest are polar vectors TWD

and assume the Plane-Wave Born Approximation (PWBA) Let us restrict our attention to the coherent elastic scattering case (C0), and assume the Plane-Wave Born Approximation (PWBA) (one can correct for this): WNC Coulomb monopole then the hadronic ratio above becomes EM Coulomb monopole Q2 in fm2 and also, for an N=Z nucleus assuming no isospin mixing and no strangeness content, one obtains the simple result: … due to G. Feinberg, Phys. Rev. D12 (1975) 3575 and J. D. Walecka, Nucl. Phys. A285 (1977) 349 TWD

For the EM Coulomb monopole form factor one has Fourier transforms of the proton and neutron distributions in the nuclear ground state, normalized as indicated TWD

For the EM Coulomb monopole form factor one has Fourier transforms of the proton and neutron distributions in the nuclear ground state, normalized as indicated … or, letting average deviation TWD

Analogously the WNC Coulomb monopole result is WNC hadronic couplings … and the PV asymmetry is proportional to the ratio TWD

… and the PV asymmetry is independent of the nuclear distribution, Special case: suppose that df is zero, which occurs if the proton and neutron distributions scale … and the PV asymmetry is independent of the nuclear distribution, depending only on the nucleon form factors TWD

… and the PV asymmetry is independent of the nuclear distribution, Special case: suppose that df is zero, which occurs if the proton and neutron distributions scale … and the PV asymmetry is independent of the nuclear distribution, depending only on the nucleon form factors And if one also neglects the electric form factor of the neutron (which is small at low momentum transfers), a very simple result is obtained: Coherent contribution TWD

of the neutron and the strangeness form factor Alternatively, retaining df, but ignoring both the electric form factor of the neutron and the strangeness form factor (both must be proportional to Q2 at low momentum transfers) … this allows one to extract information on df, specifically, the difference in the rms radii of the proton and neutron distributions in the nucleus, as originally discussed in DDS and used to motivate the PREX experiment at JLab TWD

Some specific results from Moreno and TWD: Isospin effects (12C)

Strangeness in the nucleon (see O. Moreno et al., J. Phys. G, arXiv:1408.3511v1 for discussions of what is known about strangeness in the nucleon from PV ep elastic scattering): TWD

For coherent elastic neutrino scattering one then has the following: Assumptions: tree-level SM leptonic couplings extreme relativistic limit for leptons (masses can easily be included) PWBA for electrons (Coulomb distortions can be included) single-Z0 exchange (SM) TWD

Some results from the 1981 Los Alamos report: Total elastic neutrino cross sections versus neutrino energy (here called n) using the SM TWD

Neutrino cross sections integrated from a minimum recoil energy wm up to the maximum recoil energy; SM used here. TWD

Cross sections differential in recoil angle versus f, the angle between the incident neutrino and the recoiling nucleus; SM used here. TWD

np elastic scattering using 7 different gauge theory models; #1 is the SM TWD

As above, but now for n2H elastic scattering with 3 different gauge theory models; #1 is the SM; for anti-neutrinos #2 and #3 are interchanged. TWD

Example of including strangeness versus no strangeness TWD

SUMMARY At the low momentum transfers of interest here effects from isospin mixing and strangeness are small, of order 1 percent TWD

SUMMARY At the low momentum transfers of interest here effects from isospin mixing and strangeness are small, of order 1 percent For PV electron scattering estimates of higher-order effects are even smaller, of order a few per mil (see W. Marciano talk at MIT workshop, 2012), and consequently isospin mixing, strangeness and higher-order effects are all competitive TWD

SUMMARY At the low momentum transfers of interest here effects from isospin mixing and strangeness are small, of order 1 percent For PV electron scattering estimates of higher-order effects are even smaller, of order a few per mil (see W. Marciano talk at MIT workshop, 2012), and consequently isospin mixing, strangeness and higher-order effects are all competitive Especially so because the new low-energy electron scattering facilities such as MESA at Mainz, Germany propose to measure the PV asymmetry to about dA/A = 0.003 which translates to measuring coherent neutrino scattering to about ds/s = 0.006 TWD

SUMMARY At the low momentum transfers of interest here effects from isospin mixing and strangeness are small, of order 1 percent For PV electron scattering estimates of higher-order effects are even smaller, of order a few per mil (see W. Marciano talk at MIT workshop, 2012), and consequently isospin mixing, strangeness and higher-order effects are all competitive Especially so because the new low-energy electron scattering facilities such as MESA at Mainz, Germany propose to measure the PV asymmetry to about dA/A = 0.003 which translates to measuring coherent neutrino scattering to about ds/s = 0.006 Where elastic neutrino and PV electron scattering differ the most is for incoherent elastic scattering from non-spin-zero nuclei where the axial-vector contributions in the latter are suppressed by the factor aVe = 4 sin2 qW – 1 = -0.08 meaning that potentially useful information on the NC axial-vector current could be obtained using elastic neutrino scattering from light odd-A nuclei TWD

… thank you DNP 2013 TWD 28

Coulomb distortion of the electrons (see Moreno et al. cited above): TWD

TWD