Nuclear effects in g1A(x,Q2) at small x in deep inelastic scattering on 7Li and 3He

Abstract

We suggest to use polarized nuclear targets of 7Li and 3He to study nuclear effects in the spin dependent structure functions g1A(x,Q2). These effects are expected to be enhanced by a factor of two as compared to the unpolarized targets. We predict a significant x dependence at 10-4 10-3 ≤ x ≤ 0.2 of g1A(x,Q2)/g1N(x,Q2) due to nuclear shadowing and nuclear enhancement. The effect of nuclear shadowing at x ≈ 10-3 is of an order of 16% for g1A=7n.s. 3/2(x,Q2)/g1Nn.s.(x,Q2) and 10% for g1A=3n.s(x,Q2)/g1Nn.s.(x,Q2). By imposing the requirement that the Bjorken sum rule is satisfied we model the effect of enhancement. We find the effect of enhancement at x ≈ 0.125 (0.15) to be of an order of 20 (55)% for g1A=7n.s. 3/2(x,Q2)/g1Nn.s.(x,Q2) and 14 (40)% for g1A=3n.s(x,Q2)/g1Nn.s.(x,Q2), if enhancement occupies the region 0.05 ≤ x ≤ 0.2 (0.1 ≤ x ≤ 0.2). We predict a 2% effect in the difference of the scattering cross sections of deep inelastic scattering of an unpolarized projectile off 7Li with MJ=3/2 and MJ=1/2. We also show explicitly that the many-nucleon description of deep inelastic scattering off 7Li becomes invalid in the enhancement region 0.05 < x ≤ 0.2.