Abstract
Geometric scaling is well confirmed for transverse momentum distributions observed in proton-proton collisions at LHC energies. We introduced multiplicity dependence on a saturation momentum of the geometrical scaling, assuming the scaling holds for semi-inclusive distributions as well as for inclusive distributions. The saturation momentum is usually given by Bjorken's $x$ variable, but redefinition of the scaling variable can make the saturation momentum a function of collision energy $W$. We treat the energy as a free parameter (denoted $W^*$ to distinguish it from $W$) and associate the energy-dependent saturation momentum $Q_{\rm sat}(W^*)$ with particle number density. By using $Q_{\rm sat}(W^*)$ for a scaling variable $\tau$, we show semi-inclusive distributions can be geometrically scaled. i.e., all semi-inclusive spectra observed at $W$=0.90, 2.76 and 7.00 TeV overlap one universal function. The particle density dependences of mean transverse momentum $\langle p_{\rm T} \rangle$ for LHC energies scales in terms of $Q_{\rm sat}(W^*)$. Furthermore, our model explains a scaling property of event-by-event $p_{\rm T}$ fluctuation measure $\sqrt{C_m}/\langle p_{\rm T}\rangle$ at LHC energies for pp collisions, where $C_m$ is two-particle transverse momentum correlator. Our analysis of the $p_{\rm T}$ fluctuation makes possible to evaluate a non-perturbative coefficient of the gluon correlation function.
Highlights
Studies of small collision systems in high-multiplicity events is attracting considerable interest [1] because of the collective phenomena which attribute to the formation of a strongly interacting collectively expanding quark-gluon medium [2,3,4,5]
D 2 nch d p2T dy as the case of inclusive one, we assume that there exists a saturation momentum for the spectrum classified by multiplicity as well and we propose to represent it by effective energy W ∗; i.e., 1 ST∗
II, we briefly review GS hypothesis and we confirm that it holds well for inclusive transverse spectra observed in pp collisions at Large Hadron Collider (LHC)
Summary
Studies of small collision systems in high-multiplicity events is attracting considerable interest [1] because of the collective phenomena which attribute to the formation of a strongly interacting collectively expanding quark-gluon medium [2,3,4,5]. A remarkable similarity has been observed between strange particles production in pp collisions and that in Pb-Pb collisions, suggesting the possibility of deconfined QCD phase formation in small systems [6] In such pp collisions, the charged particle pseudorapidity density rises as a power of energy [7,8], which can be explained by the theory of gluon saturation [9,10]. II for details), the saturation momentum is given by [27] If such momentum is the only scale that controls pT distribution, it should exhibit GS behavior; i.e., when one normalizes inclusive transverse-momentum spectra observed with an appropriate constant ST (interpreted later as reaction effective transverse cross-sectional area), the data points lie on a characteristic curve F (τ ) which is only depends on the.
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