Sub-eikonal stress and model dependence of the small-x gluon D-term

Abstract

The leading-eikonal small-x dipole gives a compact representation of the gluon momentum form factor Ag(t). We show that the same information is not sufficient to determine the gluon stress form factor Cg(t), and hence the gluon D-term. The reason is kinematic and operatorial: in a Drell-Yan frame Ag(t) is projected by Tg++, whereas Cg(t) is projected by the symmetric-traceless transverse stress Tgij. This stress projection first appears through next-to-eikonal fields and is represented by gauge-invariant stress-decorated Wilson lines containing Fi-, Fij, or equivalent sub-eikonal target fields. We construct this operator and match it to the local energy-momentum tensor at tree level, obtaining an operator-level no-go statement: the ordinary dipole Sx(b,r), or a saturation profile Qs2(x,b), does not by itself determine the sign of the small-x gluon D-term. We then give a finite-correlation response model in which a positive kernel generates an anti-aligned response Fi-=-εR NEFi+, so that Λ NE>0 and Dg(0)<0 within that response class. A Gaussian benchmark and numerical scans over Gaussian, Woods-Saxon, power-edge, and McLerran-Venugopalan (MV)-inspired profiles show a stable negative forward D-term for this anti-aligned model, together with the expected core-shell pressure pattern. The gluon D-term is therefore a next-to-eikonal stress probe, not a universal leading-eikonal saturation observable.

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