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Puebla May 20, 2005. Small x Physics in Deep Inelastic Scattering. J. G. Contreras ● Cinvestav Mérida. ► Motivation: Limits of pQCD, High density pQCD ► The proton at small x : F 2 , F L , F 2 c. ► Looking for saturation: Forward Jets Geometric Scaling
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Puebla May 20, 2005 SmallxPhysics in Deep Inelastic Scattering J. G. Contreras ● Cinvestav Mérida ►Motivation: Limits of pQCD, High density pQCD ►The proton at small x: F2, FL, F2c ►Looking for saturation: Forward Jets Geometric Scaling Heavy ion physics ►Summary: Very exciting field CTEQ School 2005
Motivation What are we made of ? What is the most fundamental structure of matter ? What is the structure of the proton in terms of quark and gluons? Long time ago … Today … Homework 1: and tomorrow? CTEQ School 2005
DIS: The basic idea Need a microscope to see inside the proton … produces light to see inside a proton An accelerated electron … High energy: ►Good resolution (Deep) ►Proton breaks (Inelastic) Microscope components: ► Accelerators: Fixed Target, HERA ► Detectors: H1, Zeus, … CTEQ School 2005
HERA: the only ep collider ► Asymmetric accelerator using superconducting technology ► Operating since 1992 ► 300 GeV CMS energy ► 6.3 Km of circumference ► At DESY in Hamburg CTEQ School 2005
H1 and Zeus ►Both big universal detectors with excellent tracking and calorimetry ►Built and maintained by large collaborations, each of ~ 350 scientists and around 40 institutes from around the world ►Each with more than 100 articles and several thousand citations ►Taking new data as we speak! Open detectors Note the scale Note the cables …. CTEQ School 2005
DIS in pQCD and Experiment incoming electron incoming proton outgoing electron proton remnant collision struck quark CTEQ School 2005
Description of DIS in pQCD ► Proton “=“ Σ free partons (careful with the frame) ► Two variables to describe the process to be choosen from: x: parton energy (0<x<1) Q2: resolution s: energy of CMS y: inelasticity (0<y<1) W: energy of γ*p process CTEQ School 2005
The structure of the proton according to DIS/pQCD Experiment General theory requirements pQCD: CTEQ School 2005
The limits of pQCD Perturbative solution: ►Needs small parameter ►Not all terms considered ►Free partons? Expansion parameter: ►αs (only QCD parameter) ►Its value depends on a scale (asymptotic freedom) ►In inclusive DIS scale is Q2 Resummation of ►(αs)mlogn(Q2/Qo) (DGLAP) or ►(αs)mlogn(1/x) (BFKL) CTEQ School 2005
The Nobel Prizes in DIS and pQCD DIS: ►1990 to Friedman, Kendall and Taylor Experiments at the end of 60s, early 70s ►Their results motivated the development of the quark model of the strong interaction pQCD: ►2004 to Gross, Politzer and Wilczek Theoretical work (1973), foundation of pQCD ►Discovery of asymptotic freedom (btw: read Politzer Nobel lecture!) Homework 2: You are next … CTEQ School 2005
Where are we? Where are we going? (I) Where are we? ►Basic idea of DIS and pQCD understood ►Want to explore limits of pQCD, specifically high density of partons and αs small Where are we going? ►A first look at data ►A closer look at the theory ►A second look at data CTEQ School 2005
Experiment: phase space in x and Q2 Huge phase space covered: ►x from almost 1 to ≈ 10-6 ►Q2 from less than 0.1 to almost 105 GeV2 Several overlapping regions permit cross checks between different accelerators different experiments Note the correlation between x and Q2 at small x … … smallest x outside pQCD? CTEQ School 2005
The first HERA F2 at small x Before HERA no data at small x … but many predictions based on extrapolations of existing data In 1992 the first HERA data became available: F2 (~σ) rises at small x … … and rises quite fast … lets look at it in some detail … CTEQ School 2005
Describing F2 behavior with partons Lots of partons at small x! CTEQ School 2005
F2(x,Q2) today Impressive amount of data Precision better than few % Perfect agreement between ►Hera and Fix target experiments ►Between Hera experiments Dramatic violation of Bjorken scaling Data described by fits based on DGLAP pQCD CTEQ School 2005
From F2 to pQCD partons See Stump’s talk! H1 and Zeus fits agree: ► independent data ► same theory ► different implementation … Different physics at ► large x: valence quarks ► small x: gluons and sea (note the scale factor!) Small x: ► rise dominated by gluons ► x small → log(1/x) big … CTEQ School 2005
pQCD evolution of F2: The basic idea In pQCD, F2 is computed from perturbative expansion in αssubject to constraints (RGE) → linear integral-differencial equations PDFs: ►DGLAP: log(Q2), but not log(1/x) ►BFKL: log(1/x), but ‘fixed’ Q2 Need a boundary condition to be taken from data. Given F2 in one point, one gets it at another point in phase space Both are pQCD, i.e. weak coupling needed, so none of them should work at very small Q2 … CTEQ School 2005
pQCD evolution of F2 in pictures 1 Initial structure ← exp One emission … … and another … and … BFKL: big steps in x diffusion in Q2 DGLAP: small steps in x big steps in Q2 Structure after emissions 4 2 3 3 2 2 1 1 2 3 4 We are interested in this region … but there is no scale in plot … CTEQ School 2005
High gluon density and saturation Small x, means high gluon density. The gluons are inside the proton At some point they start to overlap (the proton ‘saturates’) When they overlap, they interact, ► they are not ‘free’ anymore ► F2 stops growing ► non linear equation needed CTEQ School 2005
Where are we? Where are we going? (II) Where are we? ►free parton (DGLAP) pQCD works even at small x (where are BFKL effects?) ►Small x, means high gluon density and at some point (where?), saturation Where are we going? ►A second look at data: behavior at small x and Q2 ►Look ‘directly’ at the gluon: FL and F2C CTEQ School 2005
The Q2 dependence of the rise of F2 At small x pQCD predicts F2~x-λ ... but λ varies from BFKL expectation to those from non-perturbative QCD CTEQ School 2005
F2 and the limit Q2→ 0 Remember: W2 is energy of γ*p system At small x: W2~Q2/x → high energy Remember x and Q2 correlated at HERA At very small Q2: F2~Q2 But σγ*p ~ F2/Q2 , so at small Q2: σγ*p ~ constant, i.e. stops growing … We look for something like this at high Q2 CTEQ School 2005
Extraction of FL : the basic idea Look at high y Compare cross section to F2~x-λ Assign difference to FL(<x>,Q2) DGLAP pQCD describes data … CTEQ School 2005
F2c and the gluon A small x gluon fluctuates into a charm quark-antiquark The virtual photon interacts with one of them The struck charmed parton is kicked out of the proton It fragments into a charmed hadron, which then decays Reconstruct the hadron using specific signatures Extract F2C ~ charm PDF CTEQ School 2005
F2c : the data Lots of data High precision Big phase space Strong rise … Described by DGLAP pQCD CTEQ School 2005
Where are we? Where are we going? (III) Where are we? ►free parton pQCD works also for the gluon at small x ►no real need of BFKL up to now: where are the log(1/x)? ►No real need to go beyond free partons where is saturation? Where are we going? ►looking for BFKL effects: Forward jets ►looking for high density effects: Geometric scaling CTEQ School 2005
Forward Jets: the basic idea ► Enhance BFKL: big step in x ► Suppress DGLAP: no step in Q2 ► Experimentally look in small x for a jet at high x and with k2jet =Q2 ► i.e. Forward jets CTEQ School 2005
Forward Jets as seen by the detector 3 4 1 Initial electron and proton Scattered electron Emissions along the ladder Forward Jet Proton remnant … very difficult measurement 2 5 1 2 3 4 5 CTEQ School 2005
Forward Jets: the data ► DGLAP do not describe the measurement at small x ► ‘BFKL-like’ models describe the data, but … ► Other models also do … ► pure LL-BFKL too steep, but works with smaller ‘intercept’ Furthermore, extending BFKL beyond leading log(1/x) presents some problems … ► Anyway, strong hint of something beyond DGLAP CTEQ School 2005
Geometric Scaling From 2 variables to 1 ! CTEQ School 2005
Geometric Scaling and Saturation Why is geometric scaling interesting? ► It is an impressive phenomena ► It happens at small x ► Collapse of data points at different scales in a single curve is known to happen in phase transitions at a critical point ► Saturation may be thought as something like a phase transition: from free to interacting partons from a low to a high density system ► Some of the QCD based nonlinear equations proposed for saturation accept naturally solutions with geometric scaling behavior CTEQ School 2005
Where are we? Where are we going? (IV) Where are we? ►Inclusive and exclusive observables point to a world beyond DGLAP ►Hints of BFKL and saturation? Need denser system, still with weak coupling!! Where are we going? BEYOND ►Small x physics with nuclei ►A few words on nonlinear equations ►A final look at data CTEQ School 2005
Small x Physics and Heavy Ions Looking for a source of very dense (small x) gluons at a sizable Q2 There are many small x gluons in a proton, what about nuclei? (nuclei: lots of p’s and n’s compressed in a tight space) ► Naively expect gluon density to scale as A1/3 (high A=heavy ion) ► If energy high enough, it is possible to reach small x in the pQCD regime ► Need accelerator of ions ► Need forward detectors ► Need to disentangle all other effects Is all this possible? … let’s try and see! CTEQ School 2005
BRAHMS pp2pp PHENIX STAR Heavy ions facilities: today and tomorrow Rich history of heavy ions accelerators and experiments: AGS and SPS Today RHIC plus its detector produce beautiful data In the near future, at even higher energy, LHC and ALICE CTEQ School 2005
Color Glass Condensate: The basic idea It is a classical effective field theory of QCD with quantum evolution Valence partons act as a static random source of dynamic sea partons (Born-Oppenheimer separation based on their time scales) Static random source evolves in a time scale much larger than the natural scale like a spin glass. Lots of bosons together condensate. The new degree of freedom is the classical gluon. Gluons are colored, so call it CGC Add the corresponding RGE: Get the JIMWLK equations Limits: DGLAP, BFKL, BK eqs Phenomenology: F2, geometric scaling and … CTEQ School 2005
deuteron gold b Small x in heavy ion collisions Many handels: ► Ion species ► centrality ► CMS energy ► different x ranges For each, measure as many details as possible ► Multiplicity ► 4-momentum ► Type of particle ► Correlations ► … Here only a bit of dAu Centrality = impact parameter High η = small x in Gold CTEQ School 2005
d2N/dpTd (d+Au) RdAu = NColld2N/dpTd (p+p) x dependence of RdA Relative measurement ↔ normalization 1 = no change in physics pp vs dAu Concentrate in the higher pt values There is a x dependence … CTEQ School 2005
Rcp: x and centrality dependence Normalize central against peripheral events Study it as a function of rapidity as a function of centrality at high pt Rcp= CTEQ School 2005
Heavy Ion Physics CGC ideas quantitatively compatible with dAu Rcp data Much more data (see Seto’s talk!) CGC seems to be the right way to go, but … ► many other effects are expected to contribute ► difficult to disentangle them and ► there are some surprises A bright future at RHIC and then at LHC! CTEQ School 2005
Where are we? Where are we going? (V) Where are we? (almost!) at the end of the talk ... ►Small x physics is a very active field of research accelerators producing tons of exciting data NOW theoreticians coming up with lots of attractive ideas ►Many interesting open questions both for theory and experiment alike Where are we going? ►questions, answers… ►Next talk … ►Dinner … and beyond! THANK YOU! HOMEWORK 3 CTEQ School 2005