Isospin Decomposition of Vector and Axial Two-Body Currents via Polarized Electron--Deuteron and Electron--3He Scattering at the Electron-Ion Collider

Abstract

Two-particle two-hole (2p2h) excitations driven by meson-exchange currents (MEC) are among the leading nuclear uncertainties in long-baseline neutrino oscillation experiments. Three models currently implemented in neutrino event generators disagree by 20--40% on the ω-integrated 2p2h cross section in the dip region on carbon (differential disagreements can reach factors of 2--3), and the axial two-body current has no direct experimental constraint beyond tritium β-decay at Q2 = 0. We propose a measurement program at the Electron-Ion Collider (EIC) using polarized electron scattering on deuteron and 3He. Electromagnetic (EM) scattering (γ* exchange) measures the vector MEC. Charged-current (CC) scattering (W- exchange) on the same targets measures the vector+axial MEC. Subtracting the two provides the first direct sensitivity to the axial two-body current, including the V--A interference, as a function of momentum transfer. Using 3He (2~pn + 1~pp pair) extends the decomposition to pp pairs. Polarized beams and targets give access to six EM response functions on deuteron, four of which have not been previously measured. The tensor analyzing power provides a sign-flip test for -excitation MEC. We present projected sensitivities at 50 fb-1 on deuteron (5 years at 1033~cm-2s-1). The EM program can deliver \!5\!×\!104 events per Q2 bin constraining the MEC transverse response to 2% per bin, the beam--target double-spin asymmetry reaches 6--13σ per bin, and the vector MEC Vpn is measured to 6% per bin. The CC channel is statistics-limited, with 6--38 events per Q2 bin at 50 fb-1, requiring a luminosity upgrade beyond the current EIC baseline.