A mechanism for the<i>T</i>-odd pion fragmentation function

Gamberg, Leonard; Goldstein, Gary R.; Oganessyan, K.

doi:10.1103/physrevd.68.051501

Cited by 87 publications

(153 citation statements)

References 47 publications

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“…The beam SSA, first measured by CLAS collaboration [18] (see Fig. 2, right panel) have also been interpreted in terms of the Collins mechanism [36][37][38][39] and used for a first determination of the twist-3 distribution function e(x) [37]. The magnitude of the extracted e(x) is also consistent with predictions using the chiral quark soliton model [40][41][42].…”

Section: Spin-azimuthal Asymmetriessupporting

confidence: 60%

Structure and spin of the nucleon

Avakian

2014

EPJ Web of Conferences

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Abstract.Parton distribution functions, describing longitudinal momentum, helicity and transversity distributions of quarks and gluons, have been recently generalized to account also for transverse degrees of freedom. Two new sets of more general distributions, Transverse Momentum Distributions and Generalized Parton Distributions, were introduced to describe transverse momentum and space distributions of partons. Great progress has been made since then in measurements of different Single Spin Asymmetries (SSAs) in semi-inclusive and hard exclusive processes providing access to TMDs and GPDs, respectively. Facilities world-wide involved in studies of the 3D structure of nucleon include HERMES, COMPASS, BELLE, BaBar, Halls A, B, and C at JLab, and PHENIX and STAR at RHIC (BNL). TMD studies in the Drell-Yan process are also becoming an important part of the program of hadron scattering experiments. Studies of TMDs are also among the main driving forces of the JLab 12-GeV upgrade project, several of the forward upgrade proposals of STAR and PHENIX at RHIC, and future facilities, such as the Electron Ion Collider (EIC), FAIR in Germany, and NICA in Russia. In this contribution we present an overview of the latest developments in studies of parton distributions and discuss newly released results, ongoing activities, as well as some future measurements.

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Section: Spin-azimuthal Asymmetriessupporting

confidence: 60%

Structure and spin of the nucleon

Avakian

2014

EPJ Web of Conferences

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“…All of them produce the necessary imaginary parts by adopting a simple model for the fragmentation process at tree level and inserting one-loop corrections. Two possibilities for the tree-level amplitudes and two possible kinds of one-loop corrections have been investigated, for a total of four different models: pseudoscalar pion-quark coupling with pion loops [177] and with gluon loops [179,174]; pseudovector pion-quark coupling with pion loops [178] and with gluon loops [180]. For gluon loop cases see Fig.…”

Section: Models and Constraints For Tmd Distributionsmentioning

confidence: 99%

Azimuthal and single spin asymmetries in hard scattering processes

D’Alesio

Murgia

2008

Progress in Particle and Nuclear Physics

181

100

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In this article we review the present understanding of azimuthal and single spin asymmetries for inclusive and semi-inclusive particle production in unpolarized and polarized hadronic collisions at high energy and moderately large transverse momentum. After summarizing the experimental information available, we discuss and compare the main theoretical approaches formulated in the framework of perturbative QCD. We then present in some detail a generalization of the parton model with inclusion of spin and intrinsic transverse momentum effects. In this context, we extensively discuss the phenomenology of azimuthal and single spin asymmetries for several processes in different kinematical configurations. A comparison with the predictions of other approaches, when available, is also given. We finally emphasize some relevant open points and challenges for future theoretical and experimental investigation.

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“…Within the framework of a spectator diquark model [17][18][19][20][21] we compute both the quasi-PDFs and the standard PDFs, to study/explore for what values of P z they are good approximations of each other. This can provide guidance for future lattice QCD calculations.…”

Section: Introductionmentioning

confidence: 99%

Quasi-Parton Distribution Functions: A Study in the Diquark Spectator Model

Kang

Vitev

Xing

2016

Proceedings of QCD Evolution 2015 — PoS(QCDEV2015)

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A set of quasi-parton distribution functions (quasi-PDFs) have been recently proposed by Ji. Defined as the matrix elements of equal-time spatial correlations, they can be computed on the lattice and should reduce to the standard PDFs when the proton momentum Pz is very large. Since taking the Pz → ∞ limit is not feasible in lattice simulations, it is essential to provide guidance for what values of Pz the quasi-PDFs are good approximations of standard PDFs. Within the framework of the spectator diquark model, we evaluate both the up and down quarks' quasi-PDFs and standard PDFs for all leading-twist distributions (unpolarized distribution f1, helicity distribution g1, and transversity distribution h1). We find that, for intermediate parton momentum fractions x, quasiPDFs are good approximations to standard PDFs (within 20 − 30%) when Pz > ∼ 1.5 − 2 GeV. On the other hand, for large x ∼ 1 much larger Pz > 4 GeV is necessary to obtain a satisfactory agreement between the two sets. We further test the Soffer positivity bound, and find that it does not hold in general for quasi-PDFs.

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A mechanism for theT-odd pion fragmentation function

Cited by 87 publications

References 47 publications

Structure and spin of the nucleon

Structure and spin of the nucleon

Azimuthal and single spin asymmetries in hard scattering processes

Quasi-Parton Distribution Functions: A Study in the Diquark Spectator Model

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