26 research outputs found
Predictions for Sivers single spin asymmetries in one- and two-hadron electroproduction at CLAS12 and EIC
The study of the Sivers effect, describing correlations between the
transverse polarization of the nucleon and its constituent (unpolarized)
parton's transverse momentum, has been the topic of a great deal of
experimental, phenomenological and theoretical effort in recent years.
Semi-inclusive deep inelastic scattering measurements of the corresponding
single spin asymmetries (SSA) at the upcoming CLAS12 experiment at JLab and the
proposed Electron-Ion Collider will help to pinpoint the flavor structure and
the momentum dependence of the Sivers parton distribution function describing
this effect. Here we describe a modified version of the Monte
Carlo event generator that includes the Sivers effect. Then we use it to
estimate the size of these SSAs, in the kinematics of these experiments, for
both one and two hadron final states of pions and kaons. For this purpose we
utilize the existing Sivers parton distribution function (PDF) parametrization
extracted from HERMES and COMPASS experiments. Using this modified version of
, we also show that the the leading order approximation commonly
used in such extractions may provide significantly underestimated values of
Sivers PDFs, as in our Monte Carlo simulations the omitted parton showers and
non-DIS processes play an important role in these SSAs, for example in the
COMPASS kinematics.Comment: 18 pages, 27 figures. V2: updated to version published in PRD, two
references have been added and some minor changes done to the tex
The RHIC SPIN Program: Achievements and Future Opportunities
Time and again, spin has been a key element in the exploration of fundamental
physics. Spin-dependent observables have often revealed deficits in the assumed
theoretical framework and have led to novel developments and concepts. Spin is
exploited in many parity-violating experiments searching for physics beyond the
Standard Model or studying the nature of nucleon-nucleon forces. The RHIC spin
program plays a special role in this grand scheme: it uses spin to study how a
complex many-body system such as the proton arises from the dynamics of QCD.
Many exciting results from RHIC spin have emerged to date, most of them from
RHIC running after the 2007 Long Range Plan. In this document we present
highlights from the RHIC program to date and lay out the roadmap for the
significant advances that are possible with future RHIC running