<div>James Maxwell and Jonathan Mulholland are interested in giving contributed talks at the DNP APS meeting in Santa Fe. The deadline is tomorrow. Please review this and submit comments. The abstracts follow:</div><div><br>
</div><div>Thank you for your attention,</div><div><br></div><div>Maxwell:</div>The Spin Asymetries of the Nucleon Experiment (SANE) is a measurement of parallel and near-perpendicular double spin asymmetries in an inclusive electron scattering experiment, with the aim of calculating the spin asymmetry of the proton $A^1_p$ and structure function $g^2_p$. Using Thomas Jefferson National Accelerator Facility's polarized electron beam and the University of Virginia's polarized frozen ammonia ($^{14}$NH$_3$) target in Hall C, the experiment ran in 2009, collecting data in a Q$^2$ region from 2.5 to 6.5 GeV$^2$ in a Bjorken $x$ region of 0.3 to 0.8. Particle detection was accomplished using the Big Electron Telescope Array (BETA), a novel non-magnetic detector array with a 194 msr acceptance.<div>
This talk will address the progress of the analysis toward the calculation of the proton spin asymmetry and structure functions, including calibration of the BETA detectors, event selection, and preliminary results.</div>
<div><br></div><div>Mulholland:</div><div><div>The Spin Asymetries of the Nucleon Experiment (SANE) is an inclusive measurement of the parallel and near-perpendicular double spin asymmetries of the proton that provides access to the spin observable, A1p and structure functions, g1p and g2p. The experiment ran in early 2009, using Thomas Jefferson National Laboratory's polarized electron beam and the University of Virginia's polarized frozen ammonia target in Hall C, collecting data in a Q^2 region from 2.5 to 6.5 GeV^2 and a Bjorken x region of 0.3 to 0.8. Particle detection was accomplished using the Big Electron Telescope Array (BETA), a novel non-magnetic detector array with a 194 msr acceptance.</div>
<div>The experimental motivations and goals will be discussed in the context of current world data of the proton spin structure functions. Th experimental methods will also be presented along with an overview of the analysis status and results. Current collaboration analysis effort is focused primarily on the proton spin structure functions g1 and g2, but also includes a calculation of the proton form factor ratio, GE/GM.</div>
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