Abstract
A measurement is presented of a ratio observable that provides a measure of the azimuthal correlations among jets with large transverse momentum \(p_{\textrm{T}}\). This observable is measured in multijet events over the range of \(p_{\textrm{T}} = 360\)–\(3170\,\text {Ge}\hspace{-.08em}\text {V} \) based on data collected by the CMS experiment in proton-proton collisions at a centre-of-mass energy of 13\(\,\text {Te}\hspace{-.08em}\text {V}\), corresponding to an integrated luminosity of 134\(\,\text {fb}^{-1}\). The results are compared with predictions from Monte Carlo parton-shower event generator simulations, as well as with fixed-order perturbative quantum chromodynamics (pQCD) predictions at next-to-leading-order (NLO) accuracy obtained with different parton distribution functions (PDFs) and corrected for nonperturbative and electroweak effects. Data and theory agree within uncertainties. From the comparison of the measured observable with the pQCD prediction obtained with the NNPDF3.1 NLO PDFs, the strong coupling at the Z boson mass scale is \(\alpha _\textrm{S} (m_{{\textrm{Z}}}) =0.1177 \pm 0.0013\, \text {(exp)} _{-0.0073}^{+0.0116} \,\text {(theo)} = 0.1177_{-0.0074}^{+0.0117}\), where the total uncertainty is dominated by the scale dependence of the fixed-order predictions. A test of the running of \(\alpha _\textrm{S}\) in the \(\,\text {Te}\hspace{-.08em}\text {V}\) region shows no deviation from the expected NLO pQCD behaviour.
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1 Introduction
In the standard model of particle physics, the strong interaction between partons (quarks and gluons) is described by the theory of quantum chromodynamics (QCD). A key property of the strong interaction is “asymptotic freedom”, which characterizes the decreasing value of the coupling \(\alpha _\textrm{S} (Q)\) for increasingly larger momentum transfer Q that corresponds to smaller distances between the interacting partons. This property is a consequence of the non-Abelian nature of QCD, and can be theoretically derived from the renormalization group equations (RGE) [1,2,3]. Although the RGE cannot predict the absolute value of \(\alpha _\textrm{S} (Q)\), they can accurately determine its evolution as a function of the energy scale Q [4]. By comparing experimental measurements to perturbative QCD (pQCD) predictions for a given observable, the value of \(\alpha _\textrm{S} (Q)\) can be extracted at various scales [5, 6]. To compare various \(\alpha _\textrm{S} (Q)\) determinations, it is standard practice to evolve them to a common scale given by the mass of the Z boson, \(Q = m_{{\textrm{Z}}}\). The current world-average value of the QCD coupling at this reference scale is \(\alpha _\textrm{S} (m_{{\textrm{Z}}}) = 0.1180 \pm 0.0009\) [5].
This paper reports a new extraction of the \(\alpha _\textrm{S} (Q)\) coupling from multijet measurements at various energy scales in proton-proton (\({\text {p}} {\text {p}} \)) collisions at the CERN LHC. For this purpose, a ratio observable \(R_{\varDelta \phi }(p_{\textrm{T}})\), related to the azimuthal correlations among jets, is measured as a function of the jet transverse momentum \(p_{\textrm{T}}\). Similar ratio observables, based on either the distance in the plane of rapidity and azimuthal angle among jets, \(R_{\varDelta R}(p_{\textrm{T}})\) [7], or on the dijet azimuthal decorrelations, \(R_{\varDelta \phi }(H_\textrm{T})\) [8, 9], have already been used to extract the \(\alpha _\textrm{S} (Q)\) coupling at hadron colliders. The \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable is defined as:
where the denominator \(N_{\text {jet}}(p_{\textrm{T}})\) simply counts the number of jets in a given jet \(p_{\textrm{T}}\) bin, and the numerator sums the number of neighbouring jets, \(N_{\text {nbr}}^{(i)}\), around each jet i in the same \(p_{\textrm{T}}\) bin. A neighbouring jet must exceed a minimum transverse momentum of \(p_{\text {Tmin}}^{\text {nbr}}\) and be separated from jet i within a specified interval of azimuthal distance \(\varDelta \phi \): \({\varDelta \phi }_{\text {min}}<\varDelta \phi <{\varDelta \phi }_{\text {max}}\). In fixed-order predictions of jet production based on pQCD calculations, the leading-order (LO) \(2\rightarrow 2\) process is characterized by an azimuthal separation of \(\varDelta \phi = \pi \). Since the sum in the numerator runs over all jets, this would lead to two entries at \(p_{\textrm{T}} = p_\textrm{T,1} = p_\textrm{T,2}\). At next-to-leading order (NLO), the radiation of a third hard parton can give rise to a 3-jet topology with \(\varDelta \phi \) between \(2\pi /3\) and \(\pi \) with respect to the jet opposite to the hemisphere with radiation (Fig. 1, right diagrams). Hence, by fixing the azimuthal distance for neighbouring jets to \(2\pi /3<\varDelta \phi <7\pi /8\) in Eq. (1), the dijet case is avoided, and the numerator is different from zero only for events with three jets or more, whose LO cross section is proportional to \(\alpha _\textrm{S} ^{3}\). Also here, a jet pair fulfilling both the selection in \(p_{\text {Tmin}}^{\text {nbr}}\) and in \(\varDelta \phi \) leads to two entries, but potentially at different jet \(p_{\textrm{T}}\) values. On the other hand, the denominator corresponds to the inclusive jet cross section, which at LO is proportional to \(\alpha _\textrm{S} ^{2}\), such that the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable is directly proportional to \(\alpha _\textrm{S}\), at the lowest order. A representative illustration, indicating the entries to the numerator and denominator of the \(R_{\varDelta \phi }(p_{\textrm{T}})\) ratio, is shown in the left and right panels of Fig. 1 for a 2-jet and a 3-jet event, respectively.
In the ratio defined by Eq. (1) many experimental systematic uncertainties – such as those from the integrated luminosity, the jet energy scale (JES), and the jet energy resolution (JER) – cancel entirely or to a large extent. In addition, theoretical uncertainties – such as nonperturbative (NP) and parton distribution function (PDF) uncertainties – are reduced.
To rigorously account for correlations between the numerator and denominator, it is useful to consider the more general, two-dimensional jet-counting quantity, \(N(p_{\textrm{T}},n)\), which is a function of the i-th jet’s \(p_{\textrm{T}}\) and of the number n of neighbouring jets that satisfy the additional selection criteria for \(p_{\text {Tmin}}^{\text {nbr}}\) and \(\varDelta \phi \). Then, using \(N(p_{\textrm{T}},n)\), it can be shown that the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable can be also formulated as:
Such a definition allows a multidimensional unfolding of the more general quantity \(N(p_{\textrm{T}},n)\) to be performed, instead of a separate unfolding of the numerator and denominator of Eq. (1).
The measurement is performed using data collected with the CMS detector, during the LHC Run 2 data-taking period (2016–2018), corresponding to an integrated luminosity of 134\(\,\text {fb}^{-1}\) at a centre-of-mass energy of 13\(\,\text {Te}\hspace{-.08em}\text {V}\) [10,11,12]. Previous determinations of the strong coupling constant \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) using jets at hadron colliders have been reported by the CDF [13] and D0 [7, 14] Collaborations in proton-antiproton collisions at \(\sqrt{s}=1.8\) and 1.96\(\,\text {Te}\hspace{-.08em}\text {V}\) at the Fermilab Tevatron. At the LHC, determinations have been reported using \({\text {p}} {\text {p}} \) collision data from the ATLAS and CMS Collaborations at \(\sqrt{s}=7\) [15,16,17,18,19,20,21,22], 8 [9, 21,22,23,24,25], and 13 [26,27,28,29, 29,30,31,32]\(\,\text {Te}\hspace{-.08em}\text {V}\).
The paper is organized as follows. In Sect. 2 a brief description of the CMS detector is given. In Sect. 3 the event reconstruction is described. Section 4 details the measurement of the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable. Experimental results and theoretical predictions for the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable are compared in Sect. 5. The determination of \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) and the investigation of the running of the \(\alpha _\textrm{S} (Q)\) coupling are presented in Sect. 6. Finally, a summary of the paper is given in Sect. 7.
Tabulated results are provided in the HEPData record for this analysis [33].
2 The CMS detector
The central feature of the CMS apparatus is a superconducting solenoid of 6\(\text {\,m}\) internal diameter, providing a magnetic field of 3.8\(\text {\,T}\). Within the solenoid volume are a silicon pixel and strip tracker, a lead tungstate crystal electromagnetic calorimeter (ECAL), and a brass and scintillator hadron calorimeter (HCAL), each composed of a barrel and two endcap sections. Forward calorimeters extend the pseudorapidity coverage provided by the barrel and endcap detectors. Muons are measured in gas-ionization detectors embedded in the steel flux-return yoke outside the solenoid.
The electromagnetic calorimeter consists of 75 848 lead tungstate crystals, which provide coverage in pseudorapidity \(|\eta | < 1.48\) in a barrel region (EB) and \(1.48< |\eta | < 3.0\) in two endcap regions (EE). Preshower detectors consisting of two planes of silicon sensors interleaved with a total of three radiation lengths of lead are located in front of each EE detector.
In the region \(|\eta | < 1.74\), the HCAL cells have widths of 0.087 in pseudorapidity and 0.087 in azimuth (\(\phi \)). In the \(\eta \)–\(\phi \) plane, and for \(|\eta | < 1.48\), the HCAL cells map on to \(5{\times }5\) arrays of ECAL crystals to form calorimeter towers projecting radially outwards from close to the nominal interaction point. For \(|\eta | > 1.74\), the coverage of the towers increases progressively to a maximum of 0.174 in \(\varDelta \eta \) and \(\varDelta \phi \). A more detailed description of the CMS detector, together with a definition of the coordinate system used and the relevant kinematic variables, can be found in Ref. [34].
Events of interest are selected using a two-tiered trigger system. The first level (L1), composed of custom hardware processors, uses information from the calorimeters and muon detectors to select events at a rate of around 100\(\text {\,kHz}\) within a fixed latency of about 4\(\,\upmu \text {s}\) [35]. The second level, known as the high-level trigger (HLT), consists of a farm of processors running a version of the full event reconstruction software optimized for fast processing and reduces the event rate to around 1\(\text {\,kHz}\) before data storage [36].
3 Event reconstruction
The global event reconstruction – also called particle-flow (PF) event reconstruction [37] – aims to reconstruct and identify each individual particle in an event, with an optimized combination of all subdetector information. In this process, the identification of the particle type (photon, electron, muon, charged hadron, neutral hadron) plays an important role in the determination of the particle direction and energy. Photons (e.g., coming from \({{{\varvec{\uppi }}}}^{0}\)decays or from electron bremsstrahlung) are identified as ECAL energy clusters not linked to the extrapolation of any charged particle trajectory to the ECAL. Electrons (e.g., coming from photon conversions in the tracker material or from bottom quark (\({\text {b }} \)) hadron semileptonic decays) are identified as a primary charged particle track and potentially many ECAL energy clusters corresponding to this track extrapolation to the ECAL and to possible bremsstrahlung photons emitted along the way through the tracker material. Muons (e.g., from \({\text {b }} \)hadron semileptonic decays) are identified as tracks in the central tracker consistent with either a track or several hits in the muon system, and associated with calorimeter deposits compatible with the muon hypothesis. Charged hadrons are identified as charged particle tracks neither identified as electrons, nor as muons. Finally, neutral hadrons are identified as HCAL energy clusters not linked to any charged-hadron trajectory, or as a combined ECAL and HCAL energy excess with respect to the expected charged-hadron energy deposit.
The energy of photons is obtained from the ECAL measurement. The energy of electrons is determined from a combination of the track momentum at the main interaction vertex, the corresponding ECAL cluster energy, and the energy sum of all bremsstrahlung photons attached to the track. The energy of muons is obtained from the corresponding track momentum. The energy of charged hadrons is determined from a combination of the track momentum and the corresponding ECAL and HCAL energies, corrected for the response function of the calorimeters to hadronic showers. Finally, the energy of neutral hadrons is obtained from the corresponding corrected ECAL and HCAL energies.
The primary vertex (PV) is taken to be the vertex corresponding to the hardest scattering in the event, evaluated using tracking information alone, as described in Section 9.4.1 of Ref. [38]. For each event, hadronic jets are clustered from the reconstructed particle candidates using the infrared and collinear safe anti-\(k_{\textrm{T}}\) algorithm [39, 40] with a distance parameter of \(R=0.7\). This choice of the parameter R enables the compatibility with previous results from the CMS Collaboration at \(\sqrt{s}=7\) [16] and 13 [30]\(\,\text {Te}\hspace{-.08em}\text {V}\). Jet momentum is determined as the vectorial sum of all particle momenta in the jet, and is found from simulation to be, on average, within 5 to 10% of the true momentum over the whole \(p_{\textrm{T}}\) spectrum and detector acceptance. Additional \({\text {p}} {\text {p}} \) interactions within the same, or nearby, bunch crossings (pileup) can contribute additional tracks and calorimetric energy depositions to the jet momentum. To mitigate this effect, charged particles identified to be originating from pileup vertices are discarded, and an offset correction is applied to correct for the remaining contributions [41]. The JES corrections are derived from simulation to bring the measured response of jets to that of particle-level jets on average. In situ measurements of the momentum balance in dijet, \(\text {photon} + \text {jet}\), \({\textrm{Z}} + \text {jet}\), and multijet events are used to account for any residual differences in the jet energy scale between the measured data and simulation [42]. The jet energy resolution amounts typically to 15–20% at 30\(\,\text {Ge}\hspace{-.08em}\text {V}\), 10% at 100\(\,\text {Ge}\hspace{-.08em}\text {V}\), and 5% at 1\(\,\text {Te}\hspace{-.08em}\text {V}\) [42]. Additional selection criteria are applied to each jet to remove jets potentially dominated by anomalous contributions from various subdetector components or reconstruction failures [43].
The missing transverse momentum vector \({\vec p}_{\textrm{T}}^{\hspace{1.66656pt}\text {miss}}\) is computed as the negative vector sum of the transverse momenta of all the PF candidates in an event, and its magnitude is denoted as \(p_{\textrm{T}} ^\text {miss}\) [44]. The \({\vec p}_{\textrm{T}}^{\hspace{1.66656pt}\text {miss}}\) is modified to account for corrections to the energy scale of the reconstructed jets in the event.
During the 2016-2017 data taking, a gradual shift in the timing of the inputs of the ECAL L1 trigger in the region at \(|\eta | > 2.0\) caused a specific trigger inefficiency [45], called “prefiring” hereafter. For events containing a jet with \(p_{\textrm{T}} \gtrsim 100\,\text {Ge}\hspace{-.08em}\text {V} \) in the region \(2.5< |\eta | < 3.0\), the efficiency loss is \(\approx \)10–20%, depending on \(p_{\textrm{T}}\), \(\eta \), and data-taking period.
4 Data analysis
4.1 Event selection criteria
Each event is required to have at least one offline-reconstructed PV with z coordinate satisfying the criterion \(|z_\textrm{PV} | <24\,\text {cm} \) and radial distance from the interaction point \(\rho _{\textrm{PV}}<2\,\text {cm} \). Anomalous high-\(p_{\textrm{T}} ^\text {miss}\) events can be due to a variety of reconstruction failures, detector malfunctions, or noncollision backgrounds. Such events are rejected by event filters that are designed to identify more than 85–90% of the spurious high-\(p_{\textrm{T}} ^\text {miss}\) events with a mistagging rate less than 0.1% [44]. Only events that have been accepted by at least one single-jet trigger path (described in Sect. 4.2) are included in the measurement. For the rejection of poorly reconstructed jets and jets originating from detector noise, additional quality criteria are applied to them based on their constituents [43].
The measurement is based on an inclusive jet sample that contains only jets reconstructed within the rapidity range \(|y | < 2.5\) and with transverse momenta \(p_{\textrm{T}} >50\,\text {Ge}\hspace{-.08em}\text {V} \). The \(p_{\text {Tmin}}^{\text {nbr}}\) threshold and azimuthal separation interval for neighbouring jets as defined in Eq. (1), are set to 100\(\,\text {Ge}\hspace{-.08em}\text {V}\) and \(2\pi /3<\varDelta \phi <7\pi /8\), respectively. This choice was motivated by statistical optimization, extending the phase space as much as possible, and guaranteeing that the NLO predictions remain valid and soft effects are negligible.
4.2 Triggers
The analysis is based on single-jet triggers that require at least one jet with \(p_{\textrm{T}}\) above a given threshold \((p_{\textrm{T}} ^{\text {thresh}})\) to be present in the event. Table 1 shows the different HLT thresholds along with the effective integrated luminosities recorded by the triggers for 2016, 2017 and 2018. All triggers in Table 1 were prescaled, apart from trigger 450 for 2016, and trigger 500 for 2017 and 2018. The efficiency for each trigger is estimated as a function of leading-jet \(p_{\textrm{T}}\) using a lower-threshold trigger, except for the lowest-threshold trigger efficiency. The latter is estimated using a tag-and-probe method applied to dijet topologies, which counts the jets reconstructed with the offline PF algorithm that can be matched to HLT jets, considering only the jets leading and subleading in \(p_{\textrm{T}}\). The data consist of events selected with a combination of triggers in mutually exclusive leading-jet \(p_{\textrm{T}}\) intervals. The usage of a specific trigger is enabled only in phase-space regions where its efficiency is larger than 99.5% and disabled in phase-space regions where the efficiency of a higher-threshold trigger is larger than 99.5%. The jet-counting variables are combined event-by-event by applying weights to account for the trigger prescales of each data sample.
4.3 Unfolding
To compare the experimental data with theoretical predictions, the measured distributions must be corrected for detector effects, such as finite \(p_{\textrm{T}}\) resolution and limited detector acceptance. The detector effects are parameterized through a response matrix built from simulated event samples using pythia 8.240 [46] with tunes CUETP8M1 [47] and CP5 [48], where reconstructed-level jets are matched to generator-level jets as explained next. First, the generated jets in each event are ordered by decreasing \(p_{\textrm{T}}\). Then, each generated jet is matched to the reconstructed jet with the highest \(p_{\textrm{T}}\), within a cone of radius \(\varDelta R= \sqrt{\smash [b]{(\varDelta \eta )^2+(\varDelta \phi )^2}} = 0.35\) (where \(\varDelta \eta \) and \(\varDelta \phi \) are the angular differences in pseudorapidity and azimuthal angle between the generated and reconstructed jets). The probability matrix \({\varvec{A}}\) corresponds to the row-by-row normalized response matrix. Each element \(A_{ij}\) represents the probability of a jet produced in (generator-level) bin j to be observed in (reconstructed-level) bin i. The detector effects are corrected through an unfolding procedure that accounts for bin migrations, background (fake jets, i.e., reconstructed-level jets that could not be matched to generator-level jets), and inefficiencies (missed jets, i.e., generator-level jets that could not be matched to reconstructed-level jets), and corrects the measurement from the detector level to the level of stable particles (except neutrinos) with mean decay-lengths larger than \(c\tau =10\text {\,mm} \) (where \(\tau \) denotes the mean proper lifetime of the particle).
The unfolding procedure is implemented using the TUnfold package [49]. The determination of the particle-level distribution (\({\varvec{x}}\)) is performed with the matrix pseudoinverse method [50] using a detector-level distribution (\({\varvec{y}}\)) with twice the number of bins of the particle-level distribution. The latter are defined in Table 2 (first column) and are chosen to ensure that the bin sizes remain at least twice as large as the jet \(p_{\textrm{T}}\) resolution. The unfolding solution arises from the minimization of the quantity
where \({\varvec{b}}\) is the background obtained from simulated events, and \({\varvec{V}}\) is the covariance matrix (corrected for the background) of the detector-level data including their statistical uncertainties and correlations. Instead of unfolding separately the numerator and denominator of Eq. (1), a multidimensional unfolding of the more general, equivalent quantity \(N(p_{\textrm{T}},n)\) is performed, which rigorously accounts for the numerator-denominator statistical correlations following Eq. (2).
Figure 2 shows the probability matrix for the \(N(p_{\textrm{T}},n)\) quantity. The number of events with \(n\ge 4\) is small, and \(n=3\) is the maximum number of neighbouring jets shown here. The condition number (defined as the absolute value of the ratio between the largest and smallest matrix eigenvalues) for the matrix \({\varvec{A}}\) is \({\approx }5.5\), which means that the unfolding problem is well-conditioned, and therefore no additional regularization is required.
4.4 Experimental uncertainties
The experimental uncertainties contain statistical and systematic sources that propagate to the measured distributions. The statistical uncertainties are obtained from the covariance matrix, extracted at the particle level from the \(N(p_{\textrm{T}},n)\) distribution along with the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable, as described in Sect. 4.3. The bin-to-bin correlation matrix at the particle level is shown in Fig. 3, where the value 1 \((-1)\) corresponds to fully (anti)correlated bins. The diagonal elements of the correlation matrix are by construction always unity, and the off-diagonal elements represent the bin-to-bin (anti)correlations, where the highest (lowest) value is 0.49 (\(-0.57\)). The statistical uncertainties in the \(R_{\varDelta \phi }(p_{\textrm{T}})\) measurement remain below 1% up to \({\approx }1.5\,\text {Te}\hspace{-.08em}\text {V} \) increasing to about 10% at \({\approx }3\,\text {Te}\hspace{-.08em}\text {V} \).
The calibration of the reconstructed jet energy is performed through a series of successive stages implemented in the JES correction procedure [42], as described in Sect. 3. The JES uncertainty is composed of 27 individual uncorrelated contributions, which are investigated one-by-one considering a \(\pm 1\) standard-deviation variation from their nominal value. Each variation is applied at the detector level and propagated to the particle-level measurement by repeating the unfolding procedure. Finally, the total JES uncertainty is computed as the quadratic sum of individual JES uncertainty sources, and remains below 1% up to \({\approx }1.5\,\text {Te}\hspace{-.08em}\text {V} \) increasing to about 5% at \({\approx }3\,\text {Te}\hspace{-.08em}\text {V} \). Additional variations of the trigger prefiring corrections described in Sect. 3 are applied in the same manner. The uncertainties from prefiring corrections in the \(R_{\varDelta \phi }(p_{\textrm{T}})\) measurement are smaller than 0.13%.
In simulated samples, a detailed modelling of the CMS detector is included based on the Geant4 toolkit [51]. The JER obtained in the detector simulation is generally better than that in the actual detector. Therefore, the energy of reconstructed jets in simulation is smeared out, so that the simulated JER matches the one measured in experimental data. The JER uncertainty is estimated by varying the smearing factors within \(\pm 1\) standard deviations from their nominal values, and propagated to the particle-level measurement by repeating the unfolding procedure. The JER uncertainty in the \(R_{\varDelta \phi }(p_{\textrm{T}})\) measurement is below 0.8%.
The probability distribution for the number of \({\text {p}} {\text {p}} \) interactions per bunch crossing is represented by pileup (PU) profiles. To account for differences between the measured and simulated PU profiles, the simulated events are reweighted using the PU distribution of the experimental data as a reference. An additional systematic uncertainty, which remains below 0.03%, is evaluated by varying the PU profile correction in the simulation. The model dependence introduced by unfolding is estimated from the difference in the \(R_{\varDelta \phi }(p_{\textrm{T}})\) distribution unfolded with response matrices obtained from pythia8 and MadGraph 5_amc@nlo 2.6 [52, 53] interfaced with pythia8. Additionally, the model dependence for inefficiencies (missed jets) and backgrounds (misreconstructed jets) is studied by varying separately their rates within an estimate of 5%, which largely covers the model dependence of migrations in and out of the phase space. The total model dependence uncertainties (\(\text {MC}_{\text {model}}\)) are negligible (\({<}0.01\%\)) compared with other uncertainties for the bulk of the spectrum. The trigger efficiency uncertainties are also negligible in the \(R_{\varDelta \phi }(p_{\textrm{T}})\) measurement. The \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable values along with all the experimental uncertainties are shown in Table 2.
5 Theoretical predictions
5.1 Monte Carlo event generators predictions
Experimental data are compared with predictions from herwig++ 2.7.1 [54], pythia 8.240 [46], and powheg 2.0 [55] Monte Carlo (MC) event generators obtained using the Rivet toolkit [56]. The herwig++ event generator computes the matrix elements (MEs) at LO accuracy for \(2 \rightarrow 2\) QCD scattering processes. The parton shower (PS) is simulated through successive angular-ordered emissions, and the cluster fragmentation model [57] is used for the hadronization. The underlying event (UE) activity is obtained from the simulation of multiparton interactions (MPIs) tuned to experimental data. The set of herwig++ parameters used in this analysis is that of the UE-EE-5-CTEQ6L1 tune [58] based on the CTEQ6.1M LO PDF set [59]. Similarly to herwig++, in pythia8 the MEs are calculated at LO accuracy for \(2 \rightarrow 2\) QCD scattering processes. The PS is simulated through successive \(p_{\textrm{T}}\)-ordered emissions and the hadronization mechanism employs the Lund string model [60]. Two different sets of parameters are used for pythia8, the CUETP8M1 tune [47] based on the NNPDF2.3 LO PDF set [61, 62] and the CUETP8M2 tune [63] based on the NNPDF3.0 LO PDF set [64]. The powheg [65, 66] generator, based on the Powheg box [55], generates \(2 \rightarrow 2\) matrix elements at NLO accuracy, as well as \(2 \rightarrow 3\) matrix elements at LO accuracy and uses the NNPDF3.0 NLO PDF set [64]. To simulate the PS, hadronization, and MPI processes, powheg is interfaced either with pythia8 or with herwig++.
Figure 4 (left) shows the particle-level data for the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable compared with the predictions of pythia8 tunes CUETP8M1 and CUETP8M2, and herwig++ tune UE-EE-5-CTEQ6L1 LO MC event generators. The lower panels show the corresponding ratios between the MC predictions and the measured data. Figure 4 (right) illustrates the particle-level \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable compared with powheg interfaced with pythia8 tunes CUETP8M1 and CUETP8M2, and herwig++ tune UE-EE-5-CTEQ6L1 results. The corresponding lower panels show the ratios between the powheg predictions and the measurement. The coloured band on both lower panels represents the total experimental uncertainties.
From 360 up to around 800\(\,\text {Ge}\hspace{-.08em}\text {V}\), the \(R_{\varDelta \phi }(p_{\textrm{T}})\) distribution rises as the phase space for the production of a third jet increases. Then, the distribution reaches a plateau up to around 1200\(\,\text {Ge}\hspace{-.08em}\text {V}\), followed by a decrease due to the running of \(\alpha _\textrm{S}\), and the reduced amount of gluon scatterings.
The predictions from LO herwig++ and LO pythia8 tune CUETP8M1 overestimate the measurement by \({\approx }20\%\) and \({\approx }12\)–18%, respectively. On the other hand, the predictions from the (LO) pythia8 tune CUETP8M2 give a good description of the data. Besides the PDF set, the main differences between the parameters of the two pythia8 tunes are the value of \(\alpha _\textrm{S}\) used for the initial-state shower \(\alpha _\textrm{S} ^{\text {ISR}}\), the MPI infrared regularization scale \(p_{\text {T0}}^{\text {ref}}\), and the amount of colour reconnection. Among the NLO MC predictions based on powheg, the powheg interfaced with pythia8 tune CUETP8M2 gives the best description, being \({\approx }5\)–6% away from the measurement. Finally, powheg interfaced with herwig++ tune UE-EE-5-CTEQ6L1 or with pythia8 tune CUETP8M1 overestimate the \(R_{\varDelta \phi }(p_{\textrm{T}})\) measurement by \({\approx } 12\%\) and \({\approx }10\%\), respectively.
5.2 Fixed-order predictions
Fixed-order theoretical predictions for the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable are obtained up to NLO accuracy in pQCD with the NLOJet++ program [67, 68] within the fastNLO framework [69, 70]. The predictions are extracted for several PDF sets available via the lhapdf library [71], using their default value for the strong coupling constant \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\), and alternative values, as shown in Table 3. The central reference values \(\mu _0\) for the renormalization (\(\mu _\textrm{R}\)) and factorization (\(\mu _\textrm{F}\)) scales are defined as:
where \(\hat{H}_{\textrm{T}}\) is the scalar sum of the transverse momenta of all partons in the event. This choice follows recommendations detailed in Ref. [72], which favour \(\hat{H}_{\textrm{T}}\) over \(p_{\textrm{T},\text {jet}}\) and discourage the use of \(p_{\textrm{T},\text {max}}=p_\textrm{T,1}\) as the central scale choice for inclusive jet cross sections. For 3-jet ratio observables such as \(R_{\varDelta \phi }(p_{\textrm{T}})\), Refs. [73, 74] conclude that \(\hat{H}_{\textrm{T}}/2\) is slightly preferred for comparisons with theoretical predictions at next-to-NLO accuracy. The uncertainties related to missing higher-order terms of the perturbative series are estimated using the conventional recipe [75,76,77], i.e., by varying \(\mu _\textrm{R}\) and \(\mu _\textrm{F}\) around the reference scale \(\mu _{0}\) within six combinations: \((\mu _\textrm{R}/\mu _{0},\mu _\textrm{F}/\mu _{0})=(1/2,1/2)\), (1/2, 1), (1, 1/2), (1, 2), (2, 1), (2, 2). An envelope is constructed from the various combinations, where the edges define the scale uncertainties.
Theoretical calculations are performed separately for the cross sections corresponding to the jet counts in the numerator and denominator of the \(R_{\varDelta \phi }(p_{\textrm{T}})\) ratio defined in Eq. (1). The predictions using NNPDF3.1 for the numerator (left) and denominator (right) differential cross sections (\(\textrm{d}\sigma /\textrm{d}p_{\textrm{T}} \)) at LO and NLO accuracy are shown in Fig. 5, along with the scale uncertainties (coloured bands). The lower panels in this figure display the ratios to the respective LO predictions, where the so-called NLO pQCD K factors (NLO/LO) are about 1.30–1.55 for the numerator and 1.20–1.35 for the denominator (1.08–1.15 for their ratio). The LO and NLO scale uncertainty bands overlap over the whole phase space. The NLO scale uncertainties are in the range 9–17% for the numerator and 5–10% for the denominator.
To compare fixed-order predictions at parton level with unfolded data, the former must be corrected for NP effects due to MPI and hadronization (HAD). Based on PS generators, the NP correction factors are evaluated from the ratio of the nominal over the generated cross sections when MPI and HAD effects are switched off:
The model dependence of \(C^{\text {NP}}\) is investigated using different MC event generators, namely pythia8 with tunes CUETP8M1 and CUETP8M2, herwig++ with tune UE-EE-5-CTEQ6L1, and powheg interfaced with each one of them. A simple polynomial function \(a + b p_{\textrm{T}} ^c\) (where a, b, and c are free parameters) is used to parameterize the dependence of \(C^{\text {NP}}\) on jet \(p_{\textrm{T}}\) for each MC event generator, to avoid statistical fluctuations in less populated regions of phase space. An envelope is constructed from the different MC predictions, where the central values are identified as the NP correction factors \(C^{\text {NP}}\) and the edges define the corresponding uncertainties. Figure 6 shows the NP correction factors obtained for the numerator (upper left) and denominator (upper right) of the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable. The lower panels show the final NP correction factors \(C^{\text {NP}}\) (blue line) for \(R_{\varDelta \phi }(p_{\textrm{T}})\). The red band is constructed from the envelope of individual ratios and represents the relevant uncertainties, which are less than 1%.
To further improve the accuracy, in particular at large jet \(p_{\textrm{T}}\), the theoretical predictions are complemented with electroweak (EW) corrections. The complete set of NLO corrections for three-jet production at the LHC is presented in Ref. [82]. To obtain the EW corrections for the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable, the sherpa event generator [83] is used, interfaced with recola [84, 85]. Further details on the implementation of the above interface as well as on the method used for the subtraction of NLO EW infrared divergences are reported in Refs. [86, 87], respectively. The pure NLO EW corrections for n-jet production are defined as:
where \(\sigma _{\textrm{nj}}^{\text {LO}}\) is the pure LO pQCD cross section and \(\varDelta \text {NLO}_1\) accounts for the virtual and real EW corrections. The additive and multiplicative combination of the above corrections to the cross sections are defined, respectively, as:
where \(\varDelta \text {NLO}_0\) accounts for the virtual and real QCD corrections. Figure 7 shows the EW corrections obtained for the numerator and denominator cross sections, and for the \(R_{\varDelta \phi }(p_{\textrm{T}})\) ratio. The multiplicative combination, Eq. (8), is considered as the main result, whereas the additive combination, Eq. (7) is used as an uncertainty estimate. The relative change of the central \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) result (Sect. 6), when the additive combination is used as the main result, is smaller than 0.2%. The EW corrections for \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable range from 0.2 to 5.0% and their relevant uncertainties from 0.01 to 0.53%.
Comparisons between the measurement and the theoretical predictions for the four different PDF sets are shown in Fig. 8. The PDF uncertainties in the \(R_{\varDelta \phi }(p_{\textrm{T}})\) predictions are evaluated at 68% confidence level for each PDF set following either the Hessian [88] or the MC [89] methods, and are about 1–2% in all cases. The scale uncertainties in \(R_{\varDelta \phi }(p_{\textrm{T}})\) predictions are dominant, ranging from 2 to 8%. In general, all predictions (based on the default \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) for each PDF set) are in agreement with the measurement within the experimental and theoretical uncertainties.
6 Determination of \(\alpha _\textrm{S} (m_{{\textrm{Z}}}) \)
The sensitivity of the \(R_{\varDelta \phi }(p_{\textrm{T}})\) ratio to the strong coupling constant is investigated by varying \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) for each PDF set within the ranges presented in Table 3. The \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) value in the fixed-order matrix elements calculations is also adjusted accordingly. Figure 9 shows the results for each PDF set, where the solid green (red) curves represent the maximum (minimum) \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values, and the dashed black curves correspond to intermediate \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values in \(\varDelta \alpha _\textrm{S} (m_{{\textrm{Z}}}) = \pm 0.001\) or \(\varDelta \alpha _\textrm{S} (m_{{\textrm{Z}}}) = \pm 0.002\) steps. A large sensitivity of \(R_{\varDelta \phi }(p_{\textrm{T}})\) to variations of the strong coupling constant is observed for all PDF sets, and hence \(R_{\varDelta \phi }(p_{\textrm{T}})\) can be used for the determination of \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\).
The value of \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) is determined by minimising the goodness-of-fit (\(\chi ^2\)) between the experimental measurements and the theoretical predictions. The \(\chi ^2\) is defined as:
where N is the number of measurements, \(D_{i}\) are the experimental measurements, \(T_{i}\) are the theoretical predictions and \(C_{ij}\) is the covariance matrix, which is composed of:
where \(C_{\text {stat}}\) represents the statistical uncertainty, \(C_{\text {uncor}}\) is the numerical precision of the fixed-order predictions, which is assigned as uncorrelated uncertainty to each bin, \(C_{\text {JES}}\) is the systematic uncertainty for each JES uncertainty source, \(C_{\text {unfold}} = C_{\text {JER}} + C_{\text {PU}} + C_{\text {MC}_\text {model}}\) is the systematic uncertainty induced through unfolding (representing the JER, pileup, and model uncertainties, respectively, described in Sect. 4.4), \(C_{\text {pref}}\) is the trigger prefiring uncertainty [45], and \(C_{\text {NP}}\), \(C_{\text {PDF}}\), and \(C_{\text {EW}}\) are the NP, PDF, and EW uncertainties, respectively.
The JES, unfolding, prefiring, NP, PDF, and EW uncertainties are considered as 100% correlated among \(p_{\textrm{T}}\) bins, and are treated as multiplicative. Including only the experimental (statistical, JES, unfolding, and prefiring) uncertainties in the covariance matrix composition, the central \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) result is obtained by minimising the \(\chi ^2\) with respect to \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\). The associated experimental uncertainty is estimated from the \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values, for which the \(\chi ^2\) is increased by one unit with respect to the minimum value. Figure 10 illustrates the \(\chi ^2\) minimization curves for each PDF set, which result in the \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values and their respective experimental uncertainties listed in Table 4.
The propagation of NP, PDF, and EW uncertainties is estimated separately by repeating the \(\chi ^2\) minimization procedure after including the relevant terms in Eq. (10). For the evaluation of scale uncertainties, the \(\chi ^2\) comparison between measurement and theoretical predictions is repeated for the six different combinations of \(\mu _\textrm{R}\) and \(\mu _\textrm{F}\) scales described in Sect. 5. The up/down scale uncertainties correspond to the difference between the highest/lowest and the nominal \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values, respectively. All resulting \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values for the different PDF sets are fully compatible among each other, as well as with the world average [5]. The spread of these \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values from the different PDF sets shown in Table 4, is used for the assignment of an additional uncertainty in the final \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) result due to the PDF choice. This uncertainty is evaluated from the maximum difference among the \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values determined using the NNPDF3.1 NLO PDF set, and all the other \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values determined using the other PDF sets shown in Table 4. The final result from the present analysis using the NNPDF3.1 NLO PDF set is: \(\alpha _\textrm{S} (m_{{\textrm{Z}}}) = 0.1177_{-0.0068}^{+0.0114}~\,\text {(scale)} \pm 0.0013~\,\text {(exp)} \pm 0.0011~\,\text {(NP)} \pm 0.0010~\,\text {(PDF)} \pm 0.0003~\,\text {(EW)} \pm 0.0020~\,\text {(PDF choice)}\). This result, in comparison with a selection of \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) determinations at NLO accuracy obtained from inclusive jet [7, 13, 15, 20, 24, 90,91,92], dijet [25], and multijet [7, 9, 16, 17, 19, 23, 91, 93,94,95] measurements is presented in Fig. 11.
For the investigation of the running of the strong coupling, the fitted region of \(p_{\textrm{T}} = 360\)–3170\(\,\text {Ge}\hspace{-.08em}\text {V}\) (16 points) is split into four \(p_{\textrm{T}}\) subregions: 360–700, 700–1190, 1190–1870, and 1870–3170\(\,\text {Ge}\hspace{-.08em}\text {V}\) (4 points each). The fitting procedure is repeated and the \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) and all the relevant uncertainties are determined in each subregion separately. The \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values from each subregion are evolved to \(\alpha _\textrm{S} (Q)\), where Q is chosen as the jet \(p_{\textrm{T}}\) and is calculated as a cross-section-weighted average \((\langle Q \rangle )\) for each subregion. This study is performed using the NNPDF3.1 NLO PDF set. The values of \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) and the results for \(\alpha _\textrm{S} (Q)\) evaluated at the respective \(\langle Q \rangle \) for each fitted subregion are shown in Table 5.
Figure 12 shows the energy dependence predicted by the RGE (dashed line) using the current world-average value \(\alpha _\textrm{S} (m_{{\textrm{Z}}}) = 0.1180 \pm 0.0009\) [5] together with its associated total uncertainty (yellow band). The results from the \(\alpha _\textrm{S} (Q)\) determinations in the four subregions presented in Table 5 are also shown, along with \(\alpha _\textrm{S}\) values determined at lower scales by the H1 [91, 94, 95], ZEUS [96], D0 [7, 14], CMS [16, 19, 20, 24], and ATLAS [9, 23] Collaborations. All results reported in this study are consistent with the energy dependence predicted by the RGE, and no deviation is observed from the expected behaviour up to \(\sim 2\,\text {Te}\hspace{-.08em}\text {V} \).
7 Summary
A measurement of the \(R_{\varDelta \phi }(p_{\textrm{T}})\) ratio, sensitive to azimuthal correlations in multijet events, has been presented using proton-proton collision data collected by the CMS experiment at a centre-of-mass energy of 13\(\,\text {Te}\hspace{-.08em}\text {V}\) and corresponding to an integrated luminosity of 134\(\,\text {fb}^{-1}\). The experimental data are compared with predictions from Monte Carlo (MC) event generators, pythia8 with tunes CUETP8M1 and CUETP8M2, herwig++ with tune UE-EE-5-CTEQ6L1, and powheg interfaced with each one of them. Deviations between data and MC predictions are observed in all cases, except for pythia8 tune CUETP8M2, which gives a good overall description of the measurement.
The measurement is also compared with fixed-order perturbative quantum chromodynamics (pQCD) predictions at next-to-leading-order (NLO) accuracy using the NLOJet++ package within the fastNLO framework. Those predictions are extracted for four different NLO parton distribution function (PDF) sets, ABMP16, CT18, MSHT20, and NNPDF3.1. Corrections for nonperturbative (NP) effects are evaluated using all the aforementioned MC event generators, and are applied to the fixed-order predictions. The predictions are additionally corrected for electroweak (EW) effects that become important at large jet transverse momenta. Generally, the fixed-order predictions are in agreement with the experimental data in the phase space of this analysis, and they provide a good description of the measured \(R_{\varDelta \phi }(p_{\textrm{T}})\) distribution for all PDF sets.
Based on a comparison of the measured \(R_{\varDelta \phi }(p_{\textrm{T}})\) distribution and the theoretical predictions, the strong coupling at the scale of the Z boson mass is: \(\alpha _\textrm{S} (m_{{\textrm{Z}}}) = 0.1177_{-0.0068}^{+0.0114}\,\text {(scale)}\pm 0.0013\,\text {(exp)}\pm 0.0011\,\text {(NP)}\pm 0.0010\, \text {(PDF)}\pm 0.0003\,\text {(EW)}\pm 0.0020\,\text {(PDF choice)} = 0.1177_{-0.0074}^{+0.0117}\), using calculations based on the NNPDF3.1 NLO PDF set. Alternative \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) results obtained with other PDF sets are compatible among each other, as well as with the central result of this work, and with the current world average, \(\alpha _\textrm{S} (m_{{\textrm{Z}}}) = 0.1180\pm 0.0009\). The spread of the \(\alpha _\textrm{S} (m_{{\textrm{Z}}})\) values obtained from different PDF sets is used for the assignment of the “PDF choice” uncertainty quoted in the final strong coupling constant derived here. The dominant uncertainty in this measurement originates from the scale dependence of the NLO pQCD predictions, and is expected to be significantly reduced with the future inclusion of fixed-order predictions at next-to-NLO accuracy.
The evolution of the strong coupling as a function of the energy scale, \(\alpha _\textrm{S} (Q)\), has been tested up to \(Q\approx 2\,\text {Te}\hspace{-.08em}\text {V} \), a higher scale than that probed in previous H1, ZEUS, D0, CMS, and ATLAS measurements. This test has been performed by choosing as energy scale Q the average jet transverse momentum in the different intervals considered, and no deviation from the expected NLO pQCD running of the strong coupling is observed.
Data Availability Statement
Data cannot be made available for reasons disclosed in the data availability statement. [Authors’ comment: Release and preservation of data used by the CMS Collaboration as the basis for publications https://cms-docdb.cern.ch/cgi-bin/PublicDocDB/RetrieveFile?docid=6032&filename=CMSDataPolicyV1.2.pdf &version=2 CMS data preservation, re-use and open access policy.]
Code Availability Statement
This manuscript has associated code/software in a data repository. [Authors’comment: The CMS core software is publicly available on GitHub (https://github.com/cms-sw/cmssw).]
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Acknowledgements
We thank Max Reyer, Marek Schönherr and Steffen Schumann for providing the electroweak corrections for the \(R_{\varDelta \phi }(p_{\textrm{T}})\) observable within the sherpa framework. We congratulate our colleagues in the CERN accelerator departments for the excellent performance of the LHC and thank the technical and administrative staffs at CERN and at other CMS institutes for their contributions to the success of the CMS effort. In addition, we gratefully acknowledge the computing centres and personnel of the Worldwide LHC Computing Grid and other centres for delivering so effectively the computing infrastructure essential to our analyses. Finally, we acknowledge the enduring support for the construction and operation of the LHC, the CMS detector, and the supporting computing infrastructure provided by the following funding agencies: SC (Armenia), BMBWF and FWF (Austria); FNRS and FWO (Belgium); CNPq, CAPES, FAPERJ, FAPERGS, and FAPESP (Brazil); MES and BNSF (Bulgaria); CERN; CAS, MoST, and NSFC (China); MINCIENCIAS (Colombia); MSES and CSF (Croatia); RIF (Cyprus); SENESCYT (Ecuador); ERC PRG, RVTT3 and MoER TK202 (Estonia); Academy of Finland, MEC, and HIP (Finland); CEA and CNRS/IN2P3 (France); SRNSF (Georgia); BMBF, DFG, and HGF (Germany); GSRI (Greece); NKFIH (Hungary); DAE and DST (India); IPM (Iran); SFI (Ireland); INFN (Italy); MSIP and NRF (Republic of Korea); MES (Latvia); LMTLT (Lithuania); MOE and UM (Malaysia); BUAP, CINVESTAV, CONACYT, LNS, SEP, and UASLP-FAI (Mexico); MOS (Montenegro); MBIE (New Zealand); PAEC (Pakistan); MES and NSC (Poland); FCT (Portugal); MESTD (Serbia); MCIN/AEI and PCTI (Spain); MOSTR (Sri Lanka); Swiss Funding Agencies (Switzerland); MST (Taipei); MHESI and NSTDA (Thailand); TUBITAK and TENMAK (Turkey); NASU (Ukraine); STFC (United Kingdom); DOE and NSF (USA). Individuals have received support from the Marie-Curie programme and the European Research Council and Horizon 2020 Grant, contract Nos. 675440, 724704, 752730, 758316, 765710, 824093, 101115353,101002207, and COST Action CA16108 (European Union); the Leventis Foundation; the Alfred P. Sloan Foundation; the Alexander von Humboldt Foundation; the Science Committee, project no. 22rl-037 (Armenia); the Belgian Federal Science Policy Office; the Fonds pour la Formation à la Recherche dans l’Industrie et dans l’Agriculture (FRIA-Belgium); the Agentschap voor Innovatie door Wetenschap en Technologie (IWT-Belgium); the F.R.S.-FNRS and FWO (Belgium) under the “Excellence of Science – EOS” – be.h project n. 30820817; the Beijing Municipal Science & Technology Commission, No. Z191100007219010 and Fundamental Research Funds for the Central Universities (China); the Ministry of Education, Youth and Sports (MEYS) of the Czech Republic; the Shota Rustaveli National Science Foundation, grant FR-22-985 (Georgia); the Deutsche Forschungsgemeinschaft (DFG), under Germany’s Excellence Strategy – EXC 2121 “Quantum Universe” – 390833306, and under project number 400140256 - GRK2497; the Hellenic Foundation for Research and Innovation (HFRI), Project Number 2288 (Greece); the Hungarian Academy of Sciences, the New National Excellence Program - ÚNKP, the NKFIH research grants K 131991, K 133046, K 138136, K 143460, K 143477, K 146913, K 146914, K 147048, 2020-2.2.1-ED-2021-00181, and TKP2021-NKTA-64 (Hungary); the Council of Science and Industrial Research, India; ICSC – National Research Centre for High Performance Computing, Big Data and Quantum Computing and FAIR – Future Artificial Intelligence Research, funded by the EU NexGeneration program (Italy); the Latvian Council of Science; the Ministry of Education and Science, project no. 2022/WK/14, and the National Science Center, contracts Opus 2021/41/B/ST2/01369 and 2021/43/B/ST2/01552 (Poland); the Fundação para a Ciência e a Tecnologia, grant CEECIND/01334/2018 (Portugal); the National Priorities Research Program by Qatar National Research Fund; MCIN/AEI/10.13039/501100011033, ERDF “a way of making Europe”, and the Programa Estatal de Fomento de la Investigación Científica y Técnica de Excelencia María de Maeztu, grant MDM-2017-0765 and Programa Severo Ochoa del Principado de Asturias (Spain); the Chulalongkorn Academic into Its 2nd Century Project Advancement Project, and the National Science, Research and Innovation Fund via the Program Management Unit for Human Resources & Institutional Development, Research and Innovation, grant B37G660013 (Thailand); the Kavli Foundation; the Nvidia Corporation; the SuperMicro Corporation; the Welch Foundation, contract C-1845; and the Weston Havens Foundation (USA).
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CMS Collaboration., Hayrapetyan, A., Tumasyan, A. et al. Measurement of multijet azimuthal correlations and determination of the strong coupling in proton-proton collisions at \(\sqrt{s}=13\,\text {Te}\hspace{-.08em}\text {V} \). Eur. Phys. J. C 84, 842 (2024). https://doi.org/10.1140/epjc/s10052-024-13116-7
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DOI: https://doi.org/10.1140/epjc/s10052-024-13116-7