Semi-Inclusive DIS measurements at Jefferson Lab P. Bosted for the E00-108 Collaboration (presented by B. Sawatzky) Note mes DNP, October 2009
Semi-inclusive DIS orbital motion of quarks (pt, f dependence) pion Main focus of SIDIS studies: MX orbital motion of quarks (pt, f dependence) parton distributions (separate valence, sea) X.Ji Where region I/II boundary? Can useful information come from Region II?
SIDIS kinematic plane and relevant variables pion MX Pt is transverse momentum relative to virtual photon W2=M2+Q2(1/x-1) is invariant mass of total hadronic final state
Hall C experiment E00-108 Electron beam with E=5.5 GeV Proton and Deuteron targets SIDIS measurements of both p+ and p- Electrons scattered at 24 to 36 degrees into SOS Pions detected in the HMS spectrometer Scan of z at fixed Pt=0, x=0.3 Scan of x at fixed Pt=0, z=0.55 Scan of Pt at fixed x=0.3, Pt=0 Rather low W: 2<W<3 GeV Rather low Mx: will description in terms of scattering of single quarks hold?
Z-Dependence of cross sections Good agreement with prediction using CTEQ5M PDFs and Binnewies fragmentation functions, except for z>0.7, or Mx<1.4 GeV. D or D+,D- Jlab Hall C X=0.3, Q2=2.5 GeV2, W=2.5 GeV
How Can We Verify Factorization? Neglect sea quarks and assume no pt dependence to parton distribution functions Fragmentation function dependence drops out in Leading Order [sp(p+) + sp(p-)]/[sd(p+) + sd(p-)] = [4u(x) + d(x)]/[5(u(x) + d(x))] ~ sp/sd independent of z and pt [sp(p+) - sp(p-)]/[sd(p+) - sd(p-)] = [4u(x) - d(x)]/[3(u(x) + d(x))] independent of z and pt, but more sensitive to assumptions
Duality in Pion Electroproduction ... or Why does factorization appear to work well at low energies … GRV & CTEQ, @ LO or NLO “Works” better (recall, z = 0.65 ~ Mx2 = 2.5 GeV2) “Works” worse Closed (open) symbols reflect data after (before) events from coherent r production are subtracted
More general (e,e’h) “SIDIS” framework General formalism for (e,e’h) coincidence reaction: Factorized formalism for SIDIS (e,e’h): In general, A and B are functions of (x,Q2,z,pT,f). Note: typical assumption is that that sL/sT = RDIS Determination of the pT and f dependencies are interesting in their own right potential to determine the transverse momentum distributions of quarks.
kT-dependent SIDIS pt = Pt – z kt + O(kt2/Q2) TMDu(x,kT) Schematic diagram of semi-inclusive pion electroproduction with a factorized QCD quark parton model at lowest order in as. Final transverse momentum of the detected pion Pt arises from convolution of the struck quark transverse momentum kt with the transverse momentum generated during the fragmentation pt. pt = Pt – z kt + O(kt2/Q2) Linked to framework of Transverse Momentum Dependent Parton Distributions TMDu(x,kT) f1,g1,f1T ,g1T h1, h1T ,h1L ,h1 p m x TMD
Transverse momentum dependence of SIDIS Pt dependence very similar for proton and deuterium targets, but deuterium slopes systematically smaller?
Transverse momentum dependence of SIDIS Fit to updated version of data of previous slide With severn parameter fit: important four are: (m+)2 ~ width of D+(z,pt), (m-)2 ~ width of D-(z,pt), (mu)2 ~ width of u(x,kt), (md)2 ~ width of d(x,kt) Assumptions: Factorization valid Fragmentation functions do not depend on quark flavor, Transverse momentum widths of quark and fragmentation functions are gaussian and can be added in quadrature Sea quarks are negligible Particular function form for the Cahn effect No additional higher twist effects NLO corrections can be ignored
Transverse momentum dependence of SIDIS + vs u - vs d d vs u - vs + Ellipses are fits with different systematic assumptions Black dot is from a particular di-quark model Dashed lines have equal (u,d) or (+,-) widths
Summary and Outlook All widths of expected order-or-magnitude (I.e. 0.1 to 0.2 GeV2) d-quark width may be smaller than u-quark width Technique seems promising for future studies. Huge increase in kinematic reach and statistical accuracy expected with JLab upgrade to 11 GeV. Proposal E09-017 plans to continue these studies at higher W, Q2 and Mx over a wide region of x and z.