@article{RISC6755,author = {J. Ablinger and A. Behring and J. Bluemlein and A. De Freitas and A. von Manteuffel and C. Schneider and K. Schoenwald},
title = {{The first--order factorizable contributions to the three--loop massive operator matrix elements $A_{Qg}^{(3)}$ and $Delta A_{Qg}^{(3)}$}},
language = {english},
abstract = {The unpolarized and polarized massive operator matrix elements $A_{Qg}^{(3)}$ and $Delta A_{Qg}^{(3)}$
contain first--order factorizable and non--first--order factorizable contributions in the determining
difference or differential equations of their master integrals. We compute their first--order factorizable
contributions in the single heavy mass case for all contributing Feynman diagrams. Moreover, we present the
complete color--$zeta$ factors for the cases in which also non--first--order factorizable contributions
emerge in the master integrals, but cancel in the final result as found by using the method of arbitrary high
Mellin moments. Individual contributions depend also on generalized harmonic sums and on nested finite
binomial and inverse binomial sums in Mellin $N$--space, and correspondingly, on Kummer--Poincar'e and
square--root valued alphabets in Bjorken--$x$ space. We present a complete discussion of the possibilities
of solving the present problem in $N$--space analytically and we also discuss the limitations in the present
case to analytically continue the given $N$--space expressions to $N in mathbb{C}$ by strict methods. The
representation through generating functions allows a well synchronized representation of the first--order
factorizable results over a 17--letter alphabet. We finally obtain representations in terms of iterated integrals over the
corresponding alphabet in $x$--space, also containing up to weight {sf w = 5} special constants, which can be rationalized
to Kummer--Poincar'e iterated integrals at special arguments. The analytic $x$--space representation requires
separate analyses for the intervals $x in [0,1/4], [1/4,1/2], [1/2,1]$ and $x > 1$. We also derive the small
and large $x$ limits of the first--order factorizable contributions. Furthermore, we perform comparisons to
a number of known Mellin moments, calculated by a different method for the corresponding subset of Feynman
diagrams, and an independent high--precision numerical solution of the problems.
},
journal = {Nuclear Physics B},
volume = {999},
number = {116427},
pages = {1--42},
isbn_issn = {ISSN 0550-3213},
year = {2024},
note = {arXiv:2311.00644 [hep-ph]},
refereed = {yes},
keywords = {Feynman diagram, massive operator matrix elements, computer algebra, differential equations, difference equations, coupled systems, nested integrals, nested sums},
length = {42},
url = {https://doi.org/10.1016/j.nuclphysb.2023.116427}
}