Matching of fracture functions for SIDIS in target fragmentation region

In the target fragmentation region of Semi-Inclusive Deep Inelastic Scattering, the diffractively produced hadron has small transverse momentum. If it is at order of ΛQCD, it prevents to make predictions with the standard collinear factorization. However, in this case, differential cross-sections can be predicted by the factorization with fracture functions, diffractive parton distributions. If the transverse momentum is much larger than ΛQCD but much smaller than Q which is the virtuality of the virtual photon, both factorizations apply. In this case, fracture functions can be factorized with collinear parton distributions and fragmentation functions. We study the factorization up to twist-3 level and obtain gauge invariant results. They will be helpful for modeling fracture functions and useful for resummation of large logarithm of the transverse momentum appearing in collinear factorization.

Deep inelastic scattering in the target fragmentation region

Deep inelastic scattering is one of the best place to study hadron structures. In this paper we consider the target fragmentation region deep inelastic scattering process at leading twist. The calculations are carried out by applying the collinear expansion. In the collinear expansion formalism the multiple gluon scattering is taken into account and gauge links are obtained systematically and automatically. Quantum chromodynamics is a non-Abelian gauge theory of strong interactions in which parity symmetry can be violated by the nontrivial [Formula: see text]-vacuum tunneling effects. As a result, the axial vector current is induced. By defining and decomposing the parity-odd correlator we calculate both the parity-even and parity-odd contributions to the cross-section of the target fragmentation region deep inelastic scattering. We also present the positivity bounds for these fracture functions.

Impact of Fragmentation on Commutability of Epstein-Barr Virus and Cytomegalovirus Quantitative Standards

ABSTRACT Despite the adaptation of international standards, quantitative viral load testing of transplant-associated viruses continues to be limited by interlaboratory disagreement. Studies have suggested that this disagreement and the poor commutability of standards may, in some cases, be linked to amplicon size and the fragmentation of circulating viral DNA. We evaluated target fragmentation as a cause of noncommutability and pretest fragmentation of quantitative standards as a potential means of increasing commutability and interassay agreement. Forty-two cytomegalovirus (CMV)-positive and 41 Epstein-Barr virus (EBV)-positive plasma samples, together with two different quantitative standards for each virus, were tested as unknowns using 10 different quantitative PCR assays at 5 different laboratories. Standards were tested both intact and after intentional fragmentation by ultrasonication. Quantitative agreement between methods was assessed, together with commutability, using multiple statistical approaches. Most assays yielded results within 0.5 log10 IU/ml of the mean for CMV, while for EBV a greater variability of up to 1.5 log10 IU/ml of the mean was shown. Commutability showed marked improvement following fragmentation of both CMV standards but not after fragmentation of the EBV standards. These findings confirm the impact of amplicon size and target fragmentation on commutability for CMV and suggest that for some (but not all) viruses, interlaboratory harmonization can be improved through the use of fragmented quantitative standards.

Comparative study for target fragmentation in 4He and 6Li interactions with emulsion nuclei at Elab = 3.7A GeV

The multiplicity characteristics of the grey and black particles are studied in 3.7A GeV 4He and 6Li interactions with emulsion nuclei. The dependence on the system size is examined. The data are classified according the emission direction in the 4π space. The forward or backward emitted grey particle multiplicities distributions are approximated by exponential decay law. The black particle distributions also have the decay shapes, except for the CNO target nuclei; they are shoulder-shaped curves. The production probabilities and average multiplicities increase linearly with the target size. Multiplicity correlations are carried out. Regarding the nuclear limiting fragmentation hypothesis, the grey and black particle productions are independent of the projectile size.