Privacy and Security Notice

E06-007 (run2)

Jefferson Lab Experiment E06-007 Homepage

Impulse Approximation limitations to the (e,e',p) reaction on 208Pb, identifying correlations and relativistic effects in the nulcear medium

News and announcements

  • Shift Workers: Please read and sign the COO before the start of your shift.
  • Early start: The experiment may start as early as OWL Jan 19th, please consider signing up if you can. Sign up sheet is here.
  • Several shifts still need to be filled. Please consider signing up for them if you can. You can sign up as SL or TO here.


This measurement will determine the TL asymmtery, ATL, for protons emitted forward of the three momentum transfer q and backward of q as a function of missing momentum, pmiss for the reaction 208Pb(e,e',p)207Tl. The low lying states in 207Tl will be the focus of this study using the high resolution spectrometers of Hall A. In the range of missing momenta pmiss < 300 MeV/c a complex structure in ATL is predicted within the impulse approximation. Relativistic mean field calculations predict values of ATL that deviate substantially from the predictions that do not include the enhancement of the lower component of the wave function due to dynamically relativistic effects. Spectroscopic factors will also be extracted for these low lying states and they will be compared to the ones derived at a lower Q2 and over a rane of Q2 from 0.81 to 1.97 (GeV/c)2 to establish a dependence, or lack thereof, on Q2. Cross section measurements will also be extended out to 500 MeV/c in missing momentum. An excess of strength at high pmiss has been found in a former experiment, that has been alternately attributed to long range correlation using nonrelativistic analyses, or to relativistic effects from a full relativistic analysis. This measurement will be made in fixed q,ω kinematics, q=1 GeV/c, ω = 0.433 GeV, Q2 = 0.81 (GeV/c)2. This is the first measurement of the (e,e',p) reaction in lead done at constant (q,ω) and under quasielastic conditions, χB = 1. These data will provide observables for current and future theories of long range correlations and dynamical relativistic effects in the nulcear medium.