High-energy resummation in semi-hard processes at the LHC
Creato da
Celiberto, Francesco Giovanni
Carbone, Vincenzo
Papa, Alessandro
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Dottorato di Ricerca in Scienze e Tecnologie Fisiche, Chimiche e dei Materiali. Ciclo XXIX; Semi-hard processes in the large center-of-mass energy limit offer us an
exclusive chance to test the dynamics behind strong interactions in kinematical
sectors so far unexplored, the high luminosity and the record energies
of the LHC providing us with a richness of useful data. In the Regge limit,
s jtj, fixed-order calculations in perturbative QCD based on collinear factorisation
miss the effect of large energy logarithms, which are so large to compensate
the small QCD coupling s and must therefore be accounted for to all
perturbative orders. The BFKL approach represents the most powerful tool to
perform the resummation to all orders of these large logarithms both in the
LLA, which means inclusion of all terms proportional to ( s ln(s))n, and NLA,
which means inclusion of all terms proportional to s( s ln(s))n. The inclusive
hadroproduction of forward jets with high transverse momenta separated by
a large rapidity gap at the LHC, the so-called Mueller–Navelet jets, has been
one of the most studied reactions so far. Interesting observables associated
to this process are the azimuthal correlation momenta, showing a very good
agreement with experimental data at the LHC. However, new BFKL-sensitive observables should be considered in the context of the LHC physics program.
With the aim the to further and deeply probe the dynamics of QCD in the
Regge limit, we give phenomenological predictions for four distinct semi-hard
process. On one hand, we continue the analysis of reactions with two objects identified in the final state (i) by addressing open problems in the Mueller–
Navelet sector and (ii) by studying the inclusive dihadron production in the
full NLA BKFL accuracy. Hadrons can be detected at the LHC at much smaller
values of the transverse momentum than jets, allowing us to explore an additional
kinematical range, complementary to the one studied typical of Mueller–
Navelet jets. Furthermore, this process permits to constrain not only the parton
distribution functions for the initial proton, but also the parton fragmentation
functions describing the detected hadron in the final state. On the other hand,
we show how inclusive multi-jet production processes allow us to define new,
generalised and suitable BFKL observables, where transverse momenta and
rapidities of the tagged jets, well separated in rapidity from each other, appear
in new combinations. We give the first phenomenological predictions for
the inclusive three-jet production, encoding the effects of higher-order BFKL
corrections. Then, making use of the same formalism, we present the first
complete BFKL analysis for the four-jet production.; Università degli Studi della Calabria.Soggetto
Large Hadron Collider; Particles (Nuclear physics)
Relazione
FIS/02;