The Drell-Yan process with pions and polarized nucleons

Bastami, S.; Parsamyan, B.; Pasquini, B.; Prokudin, Alexei; Schweitzer, P.

doi:10.1007/jhep02(2021)166

Cited by 12 publications

(10 citation statements)

References 163 publications

(347 reference statements)

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“…The single transversely polarized Drell-Yan process provides another way to obtain the Boer-Mulders function. In this process the sin(2ϕ − ϕ s ) asymmetry (with ϕ s , the azimuthal angle of target transverse spin) can be obtained through the convolution of the Boer-Mulders function h ⊥ 1 (x, k 2 ) and the transversity distribution h 1 (x, k 2 ) [45,46]. Recently, the sin(2ϕ − ϕ s ) asymmetry has been measured for the first time by the COMPASS experiment [47], which has used a pion beam to collide with a transversely polarized nucleon target.…”

Section: Introductionmentioning

confidence: 99%

“…The perturbative Sudakov form factor is perturbatively calculable, while the nonperturbative Sudakov form factor is usually obtained by phenomenological extraction from experimental data. Here, we probe the scale evolution of the pion Boer-Mulders function as well as the proton transversity to estimate the sin(2ϕ−ϕ S ) asymmetry at the COMPASS kinematics and compare our prediction with the latest COMPASS data [47] and the other theoretical predictions [46].…”

Section: Introductionmentioning

confidence: 99%

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Polarized gluon distribution in the proton from holographic light-front QCD

2023

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We compute the sin(2ϕ − ϕs) azimuthal asymmetry in the pion-nucleon induced Drell-Yan process within transverse momentum dependent factorization. We employ the holographic light-front pion wave functions to calculate its leading-twist transverse momentum dependent parton distributions (TMDs). The Boer-Mulders TMD of the pion is then convoluted with the transversity TMD of the proton evaluated in a light-front quark-diquark model constructed with the wave functions predicted by the soft-wall AdS/QCD to obtain the azimuthal asymmetry in the Drell-Yan process. The gluon rescattering is pivotal to predict nonzero pion Boer-Mulders TMD. We investigate the utility of a nonperturbative SU(3) gluon rescattering kernel going beyond the usual approximation of perturbative U(1) gluons. The holographic light-front QCD approach provides a powerful tool for exploring the role of nonperturbative QCD effects in the Drell-Yan process and may help to guide future experimental measurements.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Polarized gluon distribution in the proton from holographic light-front QCD

2023

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“…And, of course, there is no sharp distinction between what constitutes a Type I or a type II scenario. It is possible to merge treatments of hadron structure with the evolution formulas that were traditionally applied at much larger Q [3,[21][22][23][24], and indeed much activity over the past decade was devoted to implementing TMD evolution, in the context of hadron structure studies, in ways that include nonperturbative parts [25][26][27][28][29][30][31][32][33][34][35][36][37]. (The versions of TMD factorization and evolution that we will focus on in this paper are those rooted in, or very similar to, the CSS formalism as described in Ref.…”

Section: Introductionmentioning

confidence: 99%

“…In many models, the large transverse momentum tails are suppressed on the grounds that it is only the small transverse momentum dependence that is nonperturbative or intrinsic to the hadron structure. Examples include at least spectator models [40][41][42][43], light-cone wave function descriptions [44][45][46][47][48], bag models [49][50][51][52][53], the Nambu-Jones Lasinio model [54][55][56], calculations based on the Dyson-Schwinger equations [57], classic quark-hadron model approaches and many others [36,58,59]. As will become clear, it is easier to incorporate models like these into full evolution treatments when starting from a bottomup approach.…”

Section: Introductionmentioning

confidence: 99%

Combining nonperturbative transverse momentum dependence with TMD evolution

Gonzalez-Hernandez,

Rogers,

Sato

2022

Preprint

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Central to understanding the nonpertubative, intrinsic partonic nature of hadron structure are the concepts of transverse momentum dependent (TMD) parton distribution and fragmentation functions. A TMD factorization approach to the phenomenology of semi-inclusive processes that includes evolution, higher orders, and matching to larger transverse momentum, is ultimately necessary for reliably connecting with phenomenologically extracted nonperturbative structures, especially when widely different scales are involved. In this paper, we will address some of the difficulties that arise when phenomenological techniques that were originally designed for very high energy applications are extended to studies of hadron structures, and we will solidify the connection between standard high energy TMD implementations and the more intuitive, parton model based approaches to phenomenology that emphasize nonperturbative hadron structure. In the process, we will elaborate on differences between forward and backward TMD evolution, which in the context of this paper we call "bottom-up" and "top-down" approaches, and we will explain the advantages of a bottom-up strategy. We will also emphasize and clarify the role of the integral relations that connect TMD and collinear correlation functions. We will show explicitly how they constrain the nonperturbative "g-functions" of standard Collins-Soper-Sterman (CSS) implementations of TMD factorization. This paper is especially targeted toward phenomenologists and model builders who are interested in merging specific nonperturbative models and calculations (including lattice QCD) with TMD factorization at large Q. Our main result is a recipe for incorporating nonperturbative models into TMD factorization, and for constraining their parameters in a way that matches to perturbative QCD and evolution.

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“…The most powerful tools to study quark TMD PDFs are the measurements of the nucleon spin (in)dependent azimuthal asymmetries in SIDIS [1,4,5,7] and Drell-Yan processes [8,9]. Complementary information on TMD fragmentation process, necessary for the interpretation of SIDIS data, is obtained from e + e − measurements [10].…”

Section: Introductionmentioning

confidence: 99%

On the physics potential to study the gluon content of proton and deuteron at NICA SPD

Arbuzov

Bacchetta

Butenschoen

et al. 2020

Preprint

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The Spin Physics Detector (SPD) is a future multipurpose experiment foreseen to run at the NICA collider, which is currently under construction at the Joint Institute for Nuclear Research (JINR, Dubna, Russia). The physics program of the experiment is based on collisions of longitudinally and transversely polarized protons and deuterons at √ s up to 27 GeV and luminosity up to 10 32 cm −2 s −1 . The SPD will operate as a universal facility for comprehensive study of unpolarized and polarized gluon content of the nucleon, using different complementary probes such as: charmonia, open charm, and prompt photon production processes. The aim of this work is to make a thorough review of the physics objectives that can potentially be addressed at the SPD, underlining related theoretical aspects and discussing relevant experimental results when available. Among different pertinent phenomena particular attention is drawn to the study of the gluon helicity, gluon Sivers and Boer-Mulders functions in the nucleon, as well as the gluon transversity distribution in the deuteron, via the measurement of specific single and double spin asymmetries.

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The Drell-Yan process with pions and polarized nucleons

Cited by 12 publications

References 163 publications

Polarized gluon distribution in the proton from holographic light-front QCD

Polarized gluon distribution in the proton from holographic light-front QCD

Combining nonperturbative transverse momentum dependence with TMD evolution

On the physics potential to study the gluon content of proton and deuteron at NICA SPD

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