Comment on "QCD factorization with multihadron fragmentation functions"
Abstract
We make several comments on the recent work in Ref.~Rogers:2024nhb while also reaffirming and adding to the work in Ref.~Pitonyak:2023gjx. We show that the factorization formula for e+e- (h1·s hn)\, X in Ref.~Rogers:2024nhb is equivalent to a version one can derive using the definition of a n-hadron fragmentation function (FF) introduced in Ref.~Pitonyak:2023gjx. In addition, we scrutinize how to generalize the number density definition of a single-hadron FF to a n-hadron FF, arguing that the definition given in Ref.~Pitonyak:2023gjx should be considered the standard one. We also emphasize that the evolution equations for dihadron FFs~(DiFFs) in Ref.~Pitonyak:2023gjx have the same splitting functions as those for single-hadron FFs. Therefore, the DiFF (and n-hadron FF) definitions in Ref.~Pitonyak:2023gjx have a natural number density interpretation and are consistent with collinear factorization using the standard hard factors and evolution kernels. Moreover, we make clear that the operator definition for the DiFF D1h1h2(,Mh) written down in Ref.~Rogers:2024nhb agrees exactly with the one in Ref.~Pitonyak:2023gjx. Contrary to what is implied in Ref.~Rogers:2024nhb, this definition did not appear in the literature prior to the work in Ref.~Pitonyak:2023gjx. There also seem to be inconsistencies in how D1h1h2(,Mh) appears in previous unpolarized cross section formulas in the literature.
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