The Pixel Luminosity Telescope is a silicon pixel detector dedicated to luminosity measurement at the CMS experiment at the LHC. It is located approximately 1.75 m from the interaction point and arranged into 16 “telescopes”, with eight telescopes installed around the beam pipe at either end of the detector and each telescope composed of three individual silicon sensor planes. The per-bunch instantaneous luminosity is measured by counting events where all three planes in the telescope register a hit, using a special readout at the full LHC bunch-crossing rate of 40 MHz. The full pixel information is read out at a lower rate and can be used to determine calibrations, corrections, and systematic uncertainties for the online and offline measurements. This paper details the commissioning, operational history, and performance of the detector during Run 2 (2015–18) of the LHC, as well as preparations for Run 3, which will begin in 2022.
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Abstract Computing demands for large scientific experiments, such as the CMS experiment at the CERN LHC, will increase dramatically in the next decades. To complement the future performance increases of software running on central processing units (CPUs), explorations of coprocessor usage in data processing hold great potential and interest. Coprocessors are a class of computer processors that supplement CPUs, often improving the execution of certain functions due to architectural design choices. We explore the approach of Services for Optimized Network Inference on Coprocessors (SONIC) and study the deployment of this as-a-service approach in large-scale data processing. In the studies, we take a data processing workflow of the CMS experiment and run the main workflow on CPUs, while offloading several machine learning (ML) inference tasks onto either remote or local coprocessors, specifically graphics processing units (GPUs). With experiments performed at Google Cloud, the Purdue Tier-2 computing center, and combinations of the two, we demonstrate the acceleration of these ML algorithms individually on coprocessors and the corresponding throughput improvement for the entire workflow. This approach can be easily generalized to different types of coprocessors and deployed on local CPUs without decreasing the throughput performance. We emphasize that the SONIC approach enables high coprocessor usage and enables the portability to run workflows on different types of coprocessors.
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Free, publicly-accessible full text available October 1, 2025
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Free, publicly-accessible full text available October 1, 2025
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Free, publicly-accessible full text available October 1, 2025
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A bstract A search for Higgs boson pair (HH) production in association with a vector boson V (W or Z boson) is presented. The search is based on proton-proton collision data at a center-of-mass energy of 13 TeV, collected with the CMS detector at the LHC, corresponding to an integrated luminosity of 138 fb
− 1. Both hadronic and leptonic decays of V bosons are used. The leptons considered are electrons, muons, and neutrinos. The HH production is searched for in the decay channel. An observed (expected) upper limit at 95% confidence level of VHH production cross section is set at 294 (124) times the standard model prediction. Constraints are also set on the modifiers of the Higgs boson trilinear self-coupling,$$ \textrm{b}\overline{\textrm{b}}\textrm{b}\overline{\textrm{b}} $$ k λ , assumingk 2V= 1, and vice versa on the coupling of two Higgs bosons with two vector bosons,k 2V. The observed (expected) 95% confidence intervals of these coupling modifiers are− 37.7 <k λ < 37.2 (− 30.1 <k λ < 28.9) and− 12.2 <k 2V< 13.5 (− 7.2 <k 2V< 8.9), respectively.Free, publicly-accessible full text available October 1, 2025 -
A bstract Diboson production in association with jets is studied in the fully leptonic final states, pp → (Z/
γ *)(Z/γ *) + jets → 2ℓ 2ℓ ′ + jets, (ℓ ,ℓ ′ = e orμ ) in proton-proton collisions at a center-of-mass energy of 13 TeV. The data sample corresponds to an integrated luminosity of 138 fb− 1collected with the CMS detector at the LHC. Differential distributions and normalized differential cross sections are measured as a function of jet multiplicity, transverse momentump T, pseudorapidityη , invariant mass and ∆η of the highest-p Tand second-highest-p Tjets, and as a function of invariant mass of the four-lepton system for events with various jet multiplicities. These differential cross sections are compared with theoretical predictions that mostly agree with the experimental data. However, in a few regions we observe discrepancies between the predicted and measured values. Further improvement of the predictions is required to describe the ZZ+jets production in the whole phase space.Free, publicly-accessible full text available October 1, 2025 -
Abstract Using proton–proton collision data corresponding to an integrated luminosity of
collected by the CMS experiment at$$140\hbox { fb}^{-1}$$ , the$$\sqrt{s}= 13\,\text {Te}\hspace{-.08em}\text {V} $$ decay is observed for the first time, with a statistical significance exceeding 5 standard deviations. The relative branching fraction, with respect to the$${{{\Lambda }} _{\text {b}}^{{0}}} \rightarrow {{\text {J}/\uppsi }} {{{\Xi }} ^{{-}}} {{\text {K}} ^{{+}}} $$ decay, is measured to be$${{{\Lambda }} _{\text {b}}^{{0}}} \rightarrow {{{\uppsi }} ({2\textrm{S}})} {{\Lambda }} $$ , where the first uncertainty is statistical, the second is systematic, and the third is related to the uncertainties in$$\mathcal {B}({{{\Lambda }} _{\text {b}}^{{0}}} \rightarrow {{\text {J}/\uppsi }} {{{\Xi }} ^{{-}}} {{\text {K}} ^{{+}}} )/\mathcal {B}({{{\Lambda }} _{\text {b}}^{{0}}} \rightarrow {{{\uppsi }} ({2\textrm{S}})} {{\Lambda }} ) = [3.38\pm 1.02\pm 0.61\pm 0.03]\%$$ and$$\mathcal {B}({{{\uppsi }} ({2\textrm{S}})} \rightarrow {{\text {J}/\uppsi }} {{{\uppi }} ^{{+}}} {{{\uppi }} ^{{-}}} )$$ .$$\mathcal {B}({{{\Xi }} ^{{-}}} \rightarrow {{\Lambda }} {{{\uppi }} ^{{-}}} )$$ Free, publicly-accessible full text available October 1, 2025 -
A search for collective effects inside jets produced in proton-proton collisions is performed via correlation measurements of charged particles using the CMS detector at the CERN LHC. The analysis uses data collected at a center-of-mass energy of, corresponding to an integrated luminosity of. Jets are reconstructed with the anti-algorithm with a distance parameter of 0.8 and are required to have transverse momentum greater than 550 GeV and pseudorapidity. Two-particle correlations among the charged particles within the jets are studied as functions of the particles’ azimuthal angle and pseudorapidity separations (and) in a jet coordinate basis, where particles’,are defined relative to the direction of the jet. The correlation functions are studied in classes of in-jet charged-particle multiplicity up to. Fourier harmonics are extracted from long-range azimuthal correlation functions to characterize azimuthal anisotropy for. For low-jets, the long-range elliptic anisotropic harmonic,, is observed to decrease with. This trend is well described by Monte Carlo event generators. However, a rising trend foremerges at, hinting at a possible onset of collective behavior, which is not reproduced by the models tested. This observation yields new insights into the dynamics of jet evolution in the vacuum.
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A search is described for the production of a pair of bottom-type vectorlike quarks (VLQs) with mass greater than 1000 GeV. EachVLQ decays into aquark and a Higgs boson, aquark and aboson, or aquark and aboson. This analysis considers both fully hadronic final states and those containing a charged lepton pair from aboson decay. The products of theboson decay and of the hadronicorboson decays can be resolved as two distinct jets or merged into a single jet, so the final states are classified by the number of reconstructed jets. The analysis uses data corresponding to an integrated luminosity ofcollected in proton-proton collisions atwith the CMS detector at the LHC from 2016 to 2018. No excess over the expected background is observed. Lower limits are set on theVLQ mass at the 95% confidence level. These depend on theVLQ branching fractions and are 1570 and 1540 GeV for 100%and 100%, respectively. In most cases, the mass limits obtained exceed previous limits by at least 100 GeV.
© 2024 CERN, for the CMS Collaboration 2024 CERN Free, publicly-accessible full text available September 1, 2025