Holographic Open/Closed Exchange in Double Deeply Virtual Compton Scattering: Fixed-j Structural Matching to the -Basis Wilson Kernels

Abstract

We show that fixed--j holographic double deeply virtual Compton scattering (DDVCS), and its DVCS limit, give a fixed-scale structural match to the singlet conformal-OPE Wilson-kernel family of QCD in the leading-twist unpolarized singlet vector channel. The open-string C1(δ,) hypergeometric kernel was derived by Nishio--Watari; the new closed-string result is that the BPST upper Witten vertex gives the same family with a different near-boundary power count, because Δc(j) is fixed by the BPST trajectory rather than by open-Regge data. The Mellin exponent is therefore derived as δc(j)=j+Δc(j)-2=2j+γc(j) rather than inserted by hand. The even open branch gives the parallel unprotected counterpart in the projected singlet vector amplitude. At Q=μ=μ0=μ, the point is not merely that equal-endpoint evolution is trivial; it is that the ultraviolet Witten vertex has already produced the fixed--j conformal kernel before the lower conformal moment is matched. In the conformal partial-wave/CS representation, beta-proportional conformal-anomaly terms and scheme transformations are coefficient/evolution bookkeeping away from the matching point, not replacements for the projected fixed-scale hypergeometric η/ξ Wilson-kernel family. The protected/unprotected j=2 split identifies the protected closed branch with the (-) conformal partial wave and the even open branch with the unprotected (+) counterpart; these are mixed singlet eigenchannels, not literal unmixed quark/gluon operators at finite Nc. Thus, once the lower Witten vertex is matched to constrained conformal moments, the DVCS/DDVCS deconvolution problem is organized in a physical operator basis rather than in arbitrary x-space profiles.