Wang, Song Ming / Research Fellow

pi_image

Contact Information

Education

Secretary

Su, Jing-Xuan / 886-2-2789-6784

Research Interest

  • particle physics

Experience

  • Postdoc, Dept. of Physics, University of Florida
  • Visiting Scientist, Academia Sinica Institute of Physics (2006-2007)

Publication

Journal Papers

  • [1]     ATLAS Collaboration, 2020, “Determination of jet calibration and energy resolution in proton–proton collisions at sqrt(s)=8 TeV using the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 1104 (2020).

  • [2]     ATLAS Collaboration, 2020, “Evidence for tttt production in the multilepton final state in proton–proton collisions at sqrt{s}=13 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80, 1085 (2020).

  • [3]     ATLAS Collaboration, 2020, “Reconstruction and identification of boosted di-tau systems in a search for Higgs boson pairs using 13 TeV proton-proton collision data in ATLAS”, JOURNAL OF HIGH ENERGY PHYSICS, 11 (2020) 163.

  • [4]     ATLAS collaboration, 2020, “Search for new non-resonant phenomena in high-mass dilepton final states with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 11(2020), 05.

  • [5]     ATLAS Collaboration, 2020, “Search for top squarks in events with a Higgs or Z boson using 139 fb−1 of pp collision data at sqrt(s)=13 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80 (2020) 1080.

  • [6]     ATLAS Collaboration, 2020, “Higgs boson production cross-section measurements and their EFT interpretation in the 4l decay channel at sqrt(s)=13 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80(2020), 957.

  • [7]     ATLAS Collaboration, 2020, “Measurements of the Higgs boson inclusive and differential fiducial cross sections in the 4l decay channel at sqrt(s)=13 TeV”, EUROPEAN PHYSICAL JOURNAL C, 80(2020), 941.

  • [8]     ATLAS Collaboration, 2020, “Search for direct production of electroweakinos in final states with missing transverse momentum and a Higgs boson decaying into photons in pp collisions at sqrt(s)= 13 TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 10 (2020) 005.

  • [9]     ATLAS Collaboration, 2020, “Search for pairs of scalar leptoquarks decaying into quarks and electrons or muons in sqrt(S)=13 TeV pp collisions with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 10 (2020) 112.

  • [10]     ATLAS Collaboration, 2020, “Search for tt resonances in fully hadronic final states in pp collisions at sqrt(s)=13 TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 10 (2020) 61.

  • [11]     ATLAS Collaboration, 2020, “CP Properties of Higgs Boson Interactions with Top Quarks in the ttH and tH Processes Using H->gammagamma with the ATLAS Detector”, PHYSICAL REVIEW LETTERS, 125(2020), 061802.

  • [12]     ATLAS Collaboration, 2020, “Measurements of top-quark pair spin correlations in the emu channel at sqrt(s)=13 TeV using pp collisions in the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80 (2020) 754.

  • [13]     ATLAS Collaboration, 2020, “Search for a scalar partner of the top quark in the all-hadronic tt plus missing transverse momentum final state at sqrt(s)=13 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80 (2020) 737.

  • [14]     ATLAS Collaboration, 2020, “Search for direct production of electroweakinos in final states with one lepton, missing transverse momentum and a Higgs boson decaying into two b-jets in pp collisions at sqrt(s)=13 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80 (2020) 691.

  • [15]     ATLAS Collaboration, 2020, “Search for long-lived, massive particles in events with a displaced vertex and a muon with large impact parameter in pp collisions at sqrt(s)=13 TeV with the ATLAS detector”, PHYSICAL REVIEW D, 102, 032006 (2020).

  • [16]     ATLAS Collaboration, 2020, “Measurement of the transverse momentum distribution of Drell–Yan lepton pairs in proton–proton collisions at sqrt(s)=13 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 616 (2020).

  • [17]     ATLAS Collaboration, 2020, “Search for Heavy Higgs Bosons Decaying into Two Tau Leptons with the ATLAS Detector Using pp Collisions at sqrt(s)=13 TeV”, PHYSICAL REVIEW LETTERS, 125(2020) 051801.

  • [18]     ATLAS Collaboration, 2020, “Search for the HH->bbbb process via vector-boson fusion production using proton-proton collisions at sqrt(s) = 13 TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 07(2020) 108.

  • [19]     ATLAS Collaboration, 2020, “Measurement of the Lund Jet Plane Using Charged Particles in 13 TeV Proton-Proton Collisions with the ATLAS Detector”, PHYSICAL REVIEW LETTERS, 124(2020), 222002.

  • [20]     ATLAS Collaboration, 2020, “Measurement of the tt production cross-section and lepton differential distributions in emu dilepton events from pp collisions at sqrt(s)=13 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80 (2020) 528.

  • [21]     ATLAS Collaboration, 2020, “Search for dijet resonances in events with an isolated charged lepton using sqrt(s)=13 TeV proton-proton collision data collected by the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 06(2020) 151.

  • [22]     ATLAS Collaboration, 2020, “Search for light long-lived neutral particles produced in pp collisions at sqrt(s)=13 TeV and decaying into collimated leptons or light hadrons with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80 (2020) 450.

  • [23]     ATLAS Collaboration, 2020, “ATLAS data quality operations and performance for 2015-2018 data taking”, JOURNAL OF INSTRUMENTATION, 15(2020), P04003.

  • [24]     ATLAS Collaboration, 2020, “Search for chargino-neutralino production with mass splittings near the electroweak scale in three-lepton final states in sqrt(s)=13 TeV pp collisions with the ATLAS detector”, PHYSICAL REVIEW D, 101 (2020) 072001.

  • [25]     ATLAS Collaboration, 2020, “Search for new resonances in mass distributions of jet pairs using 139 fb−1 of pp collisions at sqrt(s) = 13 TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 03 (2020) 145.

  • [26]     ATLAS Collaboration, 2020, “Measurement of Azimuthal Anisotropy of Muons from Charm and Bottom Hadrons in pp Collisions at sqrt(s)=13 TeV with the ATLAS Detecto”, PHYSICAL REVIEW LETTERS, 124 (2020) 082301.

  • [27]     ATLAS Collaboration, 2020, “Measurement of differential cross sections for single diffractive dissociation in sqrt(s) = 8 TeV pp collisions using the ATLAS ALFA spectrometer”, JOURNAL OF HIGH ENERGY PHYSICS, 02 (2020) 042.

  • [28]     ATLAS Collaboration, 2020, “Search for electroweak production of charginos and sleptons decaying into final states with two leptons and missing transverse momentum in sqrt(s)=13 TeV pp collisions using the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80 (2020) 123.

  • [29]     ATLAS Collaboration, 2020, “Transverse momentum and process dependent azimuthal anisotropies in sqrt(SNN)=8.16 TeV p+Pb collisions with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 80 (2020) 73.

  • [30]     ATLAS Collaboration, 2020, “A search for the dimuon decay of the Standard Model Higgs boson with the ATLAS detector”, Physics Letters B, 812 135980. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [31]     ATLAS Collaboration, 2020, “A search for the Zγ decay mode of the Higgs boson in pp collisions at s=13 TeV with the ATLAS detector”, Physics Letters B, 809 135754. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [32]     ATLAS Collaboration, 2020, “Combined measurements of Higgs boson production and decay using up to 80  fb−1 of proton-proton collision data at s=13  TeV collected with the ATLAS experiment”, Physical Review D, 101(1). (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [33]     ATLAS Collaboration, 2020, “Dijet Resonance Search with Weak Supervision Using s=13  TeV pp Collisions in the ATLAS Detector”, Physical Review Letters, 125(13). (SCIE) (IF: 8.839; SCIE ranking: 7.7%)

  • [34]     ATLAS Collaboration, 2020, “Evidence for electroweak production of two jets in association with a Zγ pair in pp collisions at s=13 TeV with the ATLAS detector”, Physics Letters B, 803 135341. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [35]     ATLAS Collaboration, 2020, “Fluctuations of anisotropic flow in Pb+Pb collisions at sNN \sqrt{{\mathrm{s}}_{\mathrm{NN}}} = 5.02 TeV with the ATLAS detector”, Journal of High Energy Physics, 2020(1). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [36]     ATLAS Collaboration, 2020, “Measurement of azimuthal anisotropy of muons from charm and bottom hadrons in Pb+Pb collisions at sNN=5.02 TeV with the ATLAS detector”, Physics Letters B, 807 135595. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [37]     ATLAS Collaboration, 2020, “Measurement of isolated-photon plus two-jet production in pp collisions at s \sqrt{s} = 13 TeV with the ATLAS detector”, Journal of High Energy Physics, 2020(3). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [38]     ATLAS Collaboration, 2020, “Measurement of J/ψ production in association with a W± boson with pp data at 8 TeV”, Journal of High Energy Physics, 2020(1). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [39]     ATLAS Collaboration, 2020, “Measurement of long-range two-particle azimuthal correlations in Z-boson tagged pp collisions at \sqrt{s}=8s=8 and 13 TeV”, The European Physical Journal C, 80(1). (SCIE) (IF: 5.172; SCIE ranking: 17.2%)

  • [40]     ATLAS Collaboration, 2020, “Measurement of soft-drop jet observables in pp collisions with the ATLAS detector at s=13  TeV”, Physical Review D, 101(5). (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [41]     ATLAS Collaboration, 2020, “Measurement of the azimuthal anisotropy of charged-particle production in Xe+Xe collisions at sNN=5.44 TeV with the ATLAS detector”, Physical Review C, 101(2). (SCIE) (IF: 3.304; SCIE ranking: 30%)

  • [42]     ATLAS Collaboration, 2020, “Measurement of the jet mass in high transverse momentum Z(→bb‾)γ production at s=13TeV using the ATLAS detector”, Physics Letters B, 812 135991. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [43]     ATLAS Collaboration, 2020, “Measurement of the tt¯ production cross-section in the lepton+jets channel at s=13 TeV with the ATLAS experiment”, Physics Letters B, 810 135797. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [44]     ATLAS Collaboration, 2020, “Measurement of the Z(→ ℓ+ℓ−)γ production cross-section in pp collisions at s \sqrt{s} = 13 TeV with the ATLAS detector”, Journal of High Energy Physics, 2020(3). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [45]     ATLAS Collaboration, 2020, “Measurements of inclusive and differential cross-sections of combined t\overline{t}\gamma and tWγ production in the eμ channel at 13 TeV with the ATLAS detector”, Journal of High Energy Physics, 2020(9). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [46]     ATLAS Collaboration, 2020, “Measurements of the production cross-section for a Z boson in association with b-jets in proton-proton collisions at \sqrt{s} = 13 TeV with the ATLAS detector”, Journal of High Energy Physics, 2020(7). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [47]     ATLAS Collaboration, 2020, “Observation and Measurement of Forward Proton Scattering in Association with Lepton Pairs Produced via the Photon Fusion Mechanism at ATLAS”, Physical Review Letters, 125(26). (SCIE) (IF: 8.839; SCIE ranking: 7.7%)

  • [48]     ATLAS Collaboration, 2020, “Observation of the associated production of a top quark and a Z boson in pp collisions at \sqrt{s} = 13 TeV with the ATLAS detector”, Journal of High Energy Physics, 2020(7). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [49]     ATLAS Collaboration, 2020, “Operation of the ATLAS trigger system in Run 2”, Journal of Instrumentation, 15(10) P10004-P10004. (SCIE) (IF: 1.258; SCIE ranking: 72.1%)

  • [50]     ATLAS Collaboration, 2020, “Performance of the ATLAS muon triggers in Run 2”, Journal of Instrumentation, 15(09) P09015-P09015. (SCIE) (IF: 1.258; SCIE ranking: 72.1%)

  • [51]     ATLAS Collaboration, 2020, “Performance of the missing transverse momentum triggers for the ATLAS detector during Run-2 data taking”, Journal of High Energy Physics, 2020(8). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [52]     ATLAS Collaboration, 2020, “Performance of the upgraded PreProcessor of the ATLAS Level-1 Calorimeter Trigger”, Journal of Instrumentation, 15(11) P11016-P11016. (SCIE) (IF: 1.258; SCIE ranking: 72.1%)

  • [53]     ATLAS Collaboration, 2020, “Search for direct stau production in events with two hadronic τ -leptons in s=13  TeV pp collisions with the ATLAS detector”, Physical Review D, 101(3). (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [54]     ATLAS Collaboration, 2020, “Search for heavy neutral Higgs bosons produced in association with b -quarks and decaying into b -quarks at s=13  TeV with the ATLAS detector”, Physical Review D, 102(3). (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [55]     ATLAS Collaboration, 2020, “Search for Heavy Resonances Decaying into a Photon and a Hadronically Decaying Higgs Boson in pp Collisions at s=13  TeV with the ATLAS Detector”, Physical Review Letters, 125(25). (SCIE) (IF: 8.839; SCIE ranking: 7.7%)

  • [56]     ATLAS Collaboration, 2020, “Search for Higgs Boson Decays into a Z Boson and a Light Hadronically Decaying Resonance Using 13 TeV pp Collision Data from the ATLAS Detector”, Physical Review Letters, 125(22). (SCIE) (IF: 8.839; SCIE ranking: 7.7%)

  • [57]     ATLAS Collaboration, 2020, “Search for Higgs boson decays into two new low-mass spin-0 particles in the 4b channel with the ATLAS detector using pp collisions at s=13  TeV”, Physical Review D, 102(11). (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [58]     ATLAS Collaboration, 2020, “Search for long-lived neutral particles produced in pp collisions at s=13  TeV decaying into displaced hadronic jets in the ATLAS inner detector and muon spectrometer”, Physical Review D, 101(5). (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [59]     ATLAS Collaboration, 2020, “Search for new phenomena in final states with large jet multiplicities and missing transverse momentum using \sqrt{s} = 13 TeV proton-proton collisions recorded by ATLAS in Run 2 of the LHC”, Journal of High Energy Physics, 2020(10). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [60]     ATLAS Collaboration, 2020, “Search for resonances decaying into a weak vector boson and a Higgs boson in the fully hadronic final state produced in proton−proton collisions at s=13  TeV with the ATLAS detector”, Physical Review D, 102(11). (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [61]     ATLAS Collaboration, 2020, “Search for squarks and gluinos in final states with same-sign leptons and jets using 139 fb−1 of data collected with the ATLAS detector”, Journal of High Energy Physics, 2020(6). (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [62]     ATLAS Collaboration, 2020, “Search for tic Monopoles and Stable High-Electric-Charge Objects in 13 Tev Proton-Proton Collisions with the ATLAS Detector”, Physical Review Letters, 124(3). (SCIE) (IF: 8.839; SCIE ranking: 7.7%)

  • [63]     ATLAS Collaboration, 2020, “Searches for electroweak production of supersymmetric particles with compressed mass spectra in s=13  TeV pp collisions with the ATLAS detector”, Physical Review D, 101(5). (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [64]     ATLAS Collaboration, 2020, “Test of CP invariance in vector-boson fusion production of the Higgs boson in the H → ττ channel in proton–proton collisions at s=13TeV with the ATLAS detector”, Physics Letters B, 805 135426. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [65]     ATLAS Collaboration, 2020, “Z boson production in Pb+Pb collisions at sNN=5.02 TeV measured by the ATLAS experiment”, Physics Letters B, 802 135262. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [66]     ATLAS Collaboration, 2019, “Electron and photon performance measurements with the ATLAS detector using the 2015-2017 LHC proton-proton collision data”, JOURNAL OF INSTRUMENTATION, 14 (2019) P12006.

  • [67]     ATLAS Collaboration, 2019, “Measurement of and production in dileptonic events in collisions at 7 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 1017.

  • [68]     ATLAS Collaboration, 2019, “Measurement of angular and momentum distributions of charged particles within and around jets in Pb+Pb and collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW C, 100 (2019) 064901.

  • [69]     ATLAS Collaboration, 2019, “Measurement of flow harmonics correlations with mean transverse momentum in lead-lead and proton-lead collisions at TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL D, 79 (2019) 985.

  • [70]     ATLAS Collaboration, 2019, “Measurements of top-quark pair differential and double-differential cross-sections in the +jets channel with collisions at TeV using the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 1028.

  • [71]     ATLAS Collaboration, 2019, “Search for bottom-squark pair production with the ATLAS detector in final states containing Higgs bosons, -jets and missing transverse momentum”, JOURNAL OF HIGH ENERGY PHYSICS, 12 (2019) 060.

  • [72]     ATLAS Collaboration, 2019, “ATLAS -jet identification performance and efficiency measurement with events in collisions at TeV”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 970.

  • [73]     ATLAS Collaboration, 2019, “Evidence for the production of three massive vector bosons with the ATLAS detector”, PHYSICS LETTERS B, 798 (2019) 134913.

  • [74]     ATLAS Collaboration, 2019, “Measurement of boson production in Pb+Pb collisions at with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 935.

  • [75]     ATLAS Collaboration, 2019, “Measurement of -boson and -boson production cross-sections in collisions at TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 901.

  • [76]     ATLAS Collaboration, 2019, “Measurement of the production cross section for a Higgs boson in association with a vector boson in the channel in collisions at TeV with the ATLAS detector”, PHYSICS LETTERS B, 798 (2019) 134949.

  • [77]     ATLAS Collaboration, 2019, “Measurement of the top-quark mass in -jet events collected with the ATLAS detector in collisions at TeV”, JOURNAL OF HIGH ENERGY PHYSICS, 11 (2019) 150.

  • [78]     ATLAS Collaboration, 2019, “Search for a right-handed gauge boson decaying into a high-momentum heavy neutrino and a charged lepton in collisions with the ATLAS”, PHYSICS LETTERS B, 798 (2019) 134942.

  • [79]     ATLAS Collaboration, 2019, “Identification of boosted Higgs bosons decaying into -quark pairs with the ATLAS detector at 13 TeV”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 836.

  • [80]     ATLAS Collaboration, 2019, “Measurement of production in the final state with the ATLAS detector in collisions at TeV”, JOURNAL OF HIGH ENERGY PHYSICS, 1910 (2019) 127.

  • [81]     ATLAS Collaboration, 2019, “Measurement of fiducial and differential production cross-sections at 13 TeV with the ATLAS detectorMeasurement of fiducial and differential production cross-sections at 13 TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 884.

  • [82]     ATLAS Collaboration, 2019, “Measurement of the inclusive cross-section for the production of jets in association with a boson in proton-proton collisions at 8 TeV using the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 847.

  • [83]     ATLAS Collaboration, 2019, “Measurement of the inclusive isolated-photon cross section in collisions at TeV using 36 fb of ATLAS dataMeasurement of the inclusive isolated-photon cross section in collisions at TeV using 36 fb of ATLAS data”, JOURNAL OF HIGH ENERGY PHYSICS, 10 (2019) 203.

  • [84]     ATLAS Collaboration, 2019, “Observation of electroweak production of a same-sign boson pair in association with two jets in collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW LETTERS, 123 (2019) 161801.

  • [85]     ATLAS Collaboration, 2019, “Search for heavy neutral leptons in decays of bosons produced in 13 TeV collisions using prompt and displaced signatures with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 10 (2019) 265.

  • [86]     ATLAS Collaboration, 2019, “Dijet azimuthal correlations and conditional yields in and +Pb collisions at = 5.02 TeV with the ATLAS detector”, PHYSICAL REVIEW C, 100 (2019) 034903.

  • [87]     ATLAS Collaboration, 2019, “Measurement of prompt photon production in TeV +Pb collisions with ATLAS”, PHYSICS LETTERS B, 796 (2019) 230.

  • [88]     ATLAS Collaboration, 2019, “Measurement of the cross-section and charge asymmetry of bosons produced in proton-proton collisions at TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 760.

  • [89]     ATLAS Collaboration, 2019, “Properties of jet fragmentation using charged particles measured with the ATLAS detector in collisions at TeV”, PHYSICAL REVIEW D, 100 (2019) 052011.

  • [90]     ATLAS Collaboration, 2019, “Resolution of the ATLAS muon spectrometer monitored drift tubes in LHC Run 2”, JOURNAL OF INSTRUMENTATION, 14 (2019) P09011.

  • [91]     ATLAS Collaboration, 2019, “Search for a heavy charged boson in events with a charged lepton and missing transverse momentum from collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW D, 100 (2019) 052013.

  • [92]     ATLAS Collaboration, 2019, “Search for diboson resonances in hadronic final states in 139 fb of collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 1909 (2019) 091.

  • [93]     ATLAS Collaboration, 2019, “Search for excited electrons singly produced in proton-proton collisions at TeV with the ATLAS experiment at the LHC”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 803.

  • [94]     ATLAS Collaboration, 2019, “Search for high-mass dilepton resonances using 139 fb of collision data collected at 13 TeV with the ATLAS detector”, PHYSICS LETTERS B, 796 (2019) 68-87.

  • [95]     ATLAS Collaboration, 2019, “Searches for scalar leptoquarks and differential cross-section measurements in dilepton-dijet events in proton-proton collisions at a centre-of-mass energy of = 13 TeV with the ATLAS experiment”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 733.

  • [96]     ATLAS Collaboratio, 2019, “Electron reconstruction and identification in the ATLAS experiment using the 2015 and 2016 LHC proton-proton collision data at TeV”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 639.

  • [97]     ATLAS Collaboration, 2019, “Measurement of distributions sensitive to the underlying event in inclusive -boson production in pp collisions at TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 666.

  • [98]     ATLAS Collaboration, 2019, “Measurement of jet-substructure observables in top quark, boson and light jet production in proton-proton collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 08 (2019) 033.

  • [99]     ATLAS Collaboration, 2019, “Search for low-mass resonances decaying into two jets and produced in association with a photon using collisions at TeV with the ATLAS detector”, PHYSICS LETTERS B, 795 (2019) 56-75.

  • [100]     ATLAS Collaboration, 2019, “Search for the electroweak diboson production in association with a high-mass dijet system in semileptonic final states in collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW D, 100 (2019) 032007.

  • [101]     ATLAS Collaboration, 2019, “Comparison of fragmentation functions for light-quark- and gluon-dominated jets from and Pb+Pb collisions in ATLAS”, PHYSICAL REVIEW LETTERS, 123 (2019) 042001.

  • [102]     ATLAS Collaboration, 2019, “Observation of light-by-light scattering in ultraperipheral Pb+Pb collisions with the ATLAS detector”, PHYSICAL REVIEW LETTERS, 123 (2019) 052001.

  • [103]     ATLAS Collaboration, 2019, “Search for chargino and neutralino production in final states with a Higgs boson and missing transverse momentum at TeV with the ATLAS detector”, PHYSICAL REVIEW D, 100 (2019) 012006.

  • [104]     ATLAS Collaboration, 2019, “Search for scalar resonances decaying into in events with and without -tagged jets produced in proton-proton collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 1907 (2019) 117.

  • [105]     ATLAS Collaboration, 2019, “Combination of searches for invisible Higgs boson decays with the ATLAS experiment”, Physics Review Letter, 122, 231801 (2019).

  • [106]     ATLAS Collaboration, 2019, “Measurement of production cross sections and gauge boson polarisation in collisions at TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 535.

  • [107]     ATLAS Collaboration, 2019, “Modelling radiation damage to pixel sensors in the ATLAS detector”, JOURNAL OF INSTRUMENTATION, 14 (2019) P06012.

  • [108]     ATLAS Collaboration, 2019, “Observation of electroweak boson pair production in association with two jets in collisions at TeV with the ATLAS detector”, PHYSICS LETTERS B, 793 (2019) 469-492.

  • [109]     ATLAS Collaboration, 2019, “Search for invisible Higgs boson decays in vector boson fusion at TeV with the ATLAS detector”, PHYSICS LETTERS B, 793 (2019) 499-519.

  • [110]     ATLAS Collaboration, 2019, “Search for long-lived neutral particles in collisions at = 13 TeV that decay into displaced hadronic jets in the ATLAS calorimeter”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 481.

  • [111]     ATLAS Collaboratio, 2019, “Searches for third-generation scalar leptoquarks in = 13 TeV pp collisions with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 1906 (2019) 144.

  • [112]     ATLAS Collaboration, 2019, “Constraints on mediator-based dark matter and scalar dark energy models using TeV collision data collected by the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 1905 (2019) 142.

  • [113]     ATLAS Collaboration, 2019, “Measurement of , production as a function of the vector boson transverse momentum in 13 TeV collisions with the ATLAS detector”, Journal of High Energy Physics, 05 (2019) 141.

  • [114]     ATLAS Collaboration, 2019, “Measurements of inclusive and differential fiducial cross-sections of production in leptonic final states at TeV in ATLAS”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 382.

  • [115]     ATLAS Collaboration, 2019, “Search for heavy charged long-lived particles in the ATLAS detector in 36.1 fb of proton-proton collision data at TeV”, PHYSICAL REVIEW D, 99 (2019) 092007.

  • [116]     ATLAS Collaboration, 2019, “Search for heavy particles decaying into a top-quark pair in the fully hadronic final state in collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW D, 99 (2019) 092004.

  • [117]     ATLAS Collaboration, 2019, “Search for Higgs boson pair production in the decay channel using ATLAS data recorded at TeV”, JOURNAL OF HIGH ENERGY PHYSICS, 05 (2019) 124.

  • [118]     ATLAS Collaboration, 2019, “Search for large missing transverse momentum in association with one top-quark in proton-proton collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 05 (2019) 041.

  • [119]     ATLAS Collaboration, 2019, “Search for single production of vector-like quarks decaying into in collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 05 (2019) 164.

  • [120]     ATLAS Collaboration, 2019, “Search for top-quark decays with 36 fb of collision data at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 05 (2019) 123.

  • [121]     ATLAS Collaboration, 2019, “Cross-section measurements of the Higgs boson decaying into a pair of -leptons in proton-proton collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW D, 99 (2019) 072001.

  • [122]     ATLAS Collaboration, 2019, “Measurement of the and cross sections in proton-proton collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW D, 99 (2019) 072009.

  • [123]     ATLAS Collaboration, 2019, “Measurement of the four-lepton invariant mass spectrum in 13 TeV proton-proton collisions with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 04 (2019) 048.

  • [124]     ATLAS Collaboration, 2019, “Measurement of the ratio of cross sections for inclusive isolated-photon production in collisions at and TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 04 (2019) 093.

  • [125]     ATLAS Collaboration, 2019, “Measurements of fiducial and differential cross-sections of production with additional heavy-flavour jets in proton-proton collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 04 (2019) 046.

  • [126]     ATLAS Collaboration, 2019, “Performance of top-quark and -boson tagging with ATLAS in Run 2 of the LHC”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 375.

  • [127]     ATLAS Collaboration, 2019, “Search for Higgs boson pair production in the decay mode at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 04 (2019) 092.

  • [128]     ATLAS Collaboration, 2019, “Search for the production of a long-lived neutral particle decaying within the ATLAS hadronic calorimeter in association with a boson from collisions at TeV”, PHYSICAL REVIEW LETTERS, 122 (2019) 151801.

  • [129]     ATLAS Collaboration, 2019, “Study of the rare decays of and mesons into muon pairs using data collected during 2015 and 2016 with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 04 (2019) 098.

  • [130]     ATLAS Collaboration, 2019, “Electron and photon energy calibration with the ATLAS detector using 2015-2016 LHC proton-proton collision data”, JOURNAL OF INSTRUMENTATION, 14 (2019) P03017.

  • [131]     ATLAS Collaboration, 2019, “Measurement of the nuclear modification factor for inclusive jets in Pb+Pb collisions at TeV with the ATLAS detector”, Physics Letters B, 790 (2019) 108-128.

  • [132]     ATLAS Collaboration, 2019, “Measurement of the photon identification efficiencies with the ATLAS detector using LHC Run 2 data collected in 2015 and 2016”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 205.

  • [133]     ATLAS Collaboration, 2019, “Measurement of the top quark mass in the lepton+jets channel from TeV ATLAS data and combination with previous results”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 290.

  • [134]     ATLAS Collaboration, 2019, “Properties of at small opening angles in collisions with the ATLAS detector at TeV”, PHYSICAL REVIEW D, 99 (2019) 052004.

  • [135]     ATLAS Collaboration, 2019, “Search for four-top-quark production in the single-lepton and opposite-sign dilepton final states in pp collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW D, 99 (2019) 052009.

  • [136]     ATLAS Collaboration, 2019, “Search for heavy long-lived multi-charged particles in proton-proton collisions at TeV using the ATLAS detector”, PHYSICAL REVIEW D, 99 (2019) 052003.

  • [137]     ATLAS Collaboration, 2019, “Search for Higgs boson decays into a pair of light bosons in the final state in collision at 13 TeV with the ATLAS detector”, PHYSICS LETTERS B, 790 (2019) 1-21.

  • [138]     ATLAS Collaboration, 2019, “Search for long-lived particles produced in collisions at TeV that decay into displaced hadronic jets in the ATLAS muon spectrometer”, PHYSICAL REVIEW D, 99 (2019) 052005.

  • [139]     ATLAS Collaboration, 2019, “Study of the hard double-parton scattering contribution to inclusive four-lepton production in collisions at TeV with the ATLAS detector”, PHYSICS LETTERS B, 790 (2019) 595.

  • [140]     ATLAS Collaboration, 2019, “A strategy for a general search for new phenomena using data-derived signal regions and its application within the ATLAS experiment”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 120.

  • [141]     ATLAS Collaboration, 2019, “Correlated long-range mixed-harmonic fluctuations measured in , +Pb and low-multiplicity Pb+Pb collisions with the ATLAS detector”, PHYSICS LETTERS B, 789 (2019) 444-471.

  • [142]     ATLAS Collaboration, 2019, “In situ calibration of large- jet energy and mass in 13 TeV proton-proton collisions with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 135.

  • [143]     ATLAS Collaboration, 2019, “Measurement of photon-jet transverse momentum correlations in 5.02 TeV Pb+Pb and collisions with ATLAS”, PHYSICS LETTERS B, 789 (2019) 167-190.

  • [144]     ATLAS Collaboration, 2019, “Measurements of and boson production in collisions at TeV with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 128.

  • [145]     ATLAS Collaboration, 2019, “Measurements of gluon-gluon fusion and vector-boson fusion Higgs boson production cross-sections in the decay channel in collisions at TeV with the ATLAS detector”, PHYSICS LETTERS B, 789 (2019) 508-529.

  • [146]     ATLAS Collaboration, 2019, “A search for pairs of highly collimated photon-jets in collisions at = 13 TeV with the ATLAS detector”, PHYSICAL REVIEW D, 99 (2019) 012008.

  • [147]     ATLAS Collaboration, 2019, “Search for doubly charged scalar bosons decaying into same-sign boson pairs with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, 79 (2019) 58.

  • [148]     ATLAS Collaboration, 2019, “Search for heavy charged long-lived particles in proton-proton collisions at TeV using an ionisation measurement with the ATLAS detector”, PHYSICS LETTERS B, 788 (2019) 96-116.

  • [149]     ATLAS Collaboration, 2019, “Search for heavy Majorana or Dirac neutrinos and right-handed gauge bosons in final states with two charged leptons and two jets at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 1901 (2019) 016.

  • [150]     ATLAS Collaboration, 2019, “Search for long-lived particles in final states with displaced dimuon vertices in collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW D, 99 (2019) 012001.

  • [151]     ATLAS Collaboration, 2019, “Search for pair production of Higgs bosons in the final state using proton-proton collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 1901 (2019) 030.

  • [152]     ATLAS Collaboration, 2019, “Search for squarks and gluinos in final states with hadronically decaying -leptons, jets, and missing transverse momentum using collisions at = 13 TeV with the ATLAS detector”, PHYSICAL REVIEW D, 99 (2019) 012009.

  • [153]     ATLAS Collaboration, 2019, “Search for vector-boson resonances decaying to a top quark and bottom quark in the lepton plus jets final state in collisions at TeV with the ATLAS detector”, PHYSICS LETTERS B, 788 (2019) 347-370.

  • [154]     ATLAS Collaboration, 2019, “Combination of searches for Higgs boson pairs in pp collisions at s=13TeV with the ATLAS detector”, Physics Letters B, 800 135103. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [155]     ATLAS Collaboration, 2019, “Measurement of angular and momentum distributions of charged particles within and around jets in Pb+Pb and pp collisions at sNN=5.02 TeV with the ATLAS detector”, Physical Review C, 100(6). (SCIE) (IF: 3.304; SCIE ranking: 30%)

  • [156]     ATLAS Collaboration, 2019, “Measurements of top-quark pair differential and double-differential cross-sections in the \ell +jets channel with pp collisions at \sqrt{s}=13 TeV using the ATLAS detector”, The European Physical Journal C, 79(12). (SCIE) (IF: 5.172; SCIE ranking: 17.2%)

  • [157]     ATLAS Collaboration, 2019, “Search for displaced vertices of oppositely charged leptons from decays of long-lived particles in pp collisions at s=13 TeV with the ATLAS detector”, Physics Letters B, 801 135114. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [158]     ATLAS Collaboration, 2019, “Search for flavour-changing neutral currents in processes with one top quark and a photon using 81 fb−1 of pp collisions at s=13TeV with the ATLAS experiment”, Physics Letters B, 800 135082. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [159]     ATLAS Collaboration, 2019, “Search for non-resonant Higgs boson pair production in the bbℓνℓν final state with the ATLAS detector in pp collisions at s=13 TeV”, Physics Letters B, 801 135145. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [160]     ATLAS Collaboration, 2019, “Search for the Higgs boson decays H → ee and H → eμ in pp collisions at s=13TeV with the ATLAS detector”, Physics Letters B, 801 135148. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [161]     ATLAS Collaboration, 2019, “Searches for lepton-flavour-violating decays of the Higgs boson in s=13 TeV pp collisions with the ATLAS detector”, Physics Letters B, 800 135069. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [162]     ATLAS Collaboration, 2018, “Observation of ̄ decays and production with the ATLAS detector”, PHYSICS LETTERS B, 786 (2018) 59.

  • [163]     ATLAS Collaboration, 2018, “Search for dark matter in events with a hadronically decaying vector boson and missing transverse momentum in collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 10 (2018), 180.

  • [164]     ATLAS Collaboration, 2018, “Search for Higgs bosons produced via vector-boson fusion and decaying into bottom quark pairs in TeV collisions with the ATLAS detector”, PHYSICAL REVIEW D, 98 (2018) 052003.

  • [165]     ATLAS Collaboration, 2018, “Searches for resonant and non-resonant di-Higgs production in the decay channel in collisions at TeV with the ATLAS detector”, PHYSICAL REVIEW LETTERS, 121 (2018) 191801.

  • [166]     ATLAS Collaboration, 2017, “Evidence for the decay with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 12, 24. (SCIE) (IF: 6.063; SCIE ranking: 10.3%)

  • [167]     ATLAS Collaboration, 2016, “Search for an additional, heavy Higgs boson in the decay channel at TeV in collision data with the ATLAS detector”, EUROPEAN PHYSICAL JOURNAL C, Volume 76, pp. 45. (SCIE) (IF: 5.297; SCIE ranking: 13.8%)

  • [168]     ATLAS Collaboration, 2016, “Searches for heavy diboson resonances in collisions at TeV with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, Volume 9, pp. 173. (SCIE) (IF: 6.063; SCIE ranking: 10.3%)

  • [169]     ATLAS Collaboration, 2015, “Search for the bb decay of the Standard Model Higgs boson in associated (W/Z)H production with the ATLAS detector”, JOURNAL OF HIGH ENERGY PHYSICS, 01, 069. (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [170]     The CDF Collaboration. the D0 Collaboration, the Tevatron New Physics, Higgs Working Group, 2013, “Higgs boson studies at the Tevatron”, Phys. Rev. D, 88, 052014. (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [171]     ATLAS Collaboration, 2013, “Measurements of and production in pp collisions at TeV with the ATLAS detector at the LHC”, Phys. Rev. D, Volume 87, pp. 112003. (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [172]     CDF Collaboration, 2013, “Search for the Higgs boson in the all-hadronic final state using the CDF data set”, JOURNAL OF HIGH ENERGY PHYSICS, 02, 004. (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [173]     ATLAS Collaboration, 2012, “Measurement of and production cross sections in pp collisions at TeV and limits on anomalous triple gauge couplings with the ATLAS detector”, PHYSICS LETTERS B, 717, 49-69. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [174]     ATLAS Collaboration, 2012, “Observation of a new particle in the search for the Standard Model Higgs boson with the ATLAS detector at the LHC”, PHYSICS LETTERS B, 716, 1-29. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [175]     ATLAS Collaboration, 2012, “Search for the Standard Model Higgs boson produced in association with a vector boson and decaying to a b-quark pair with the ATLAS detector”, PHYSICS LETTERS B, 718, 369-390. (SCIE) (IF: 4.254; SCIE ranking: 24.2%,20%,27.6%)

  • [176]     T. Aaltonen et al., 2011, “Search for the Higgs Boson in the All-Hadronic Final State Using the CDF II Detector”, Phys. Rev. D, Volume 84, pp. 052010. (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [177]     ATLAS Collaboration, 2011, “Measurement of Wγ and Zγ production in proton-proton collisions at √s =7 TeV with the ATLAS Detector”, JOURNAL OF HIGH ENERGY PHYSICS, Volume 09, pp. 072. (SCIE) (IF: 5.541; SCIE ranking: 13.8%)

  • [178]     T. Aaltonen et al., The CDF Collaboration, 2009, “A Search for the Associated Production of the Standard Model Higgs Boson in the All-Hadronic Channel”, Phys. Rev. Lett., 103, 221801. (SCIE) (IF: 8.839; SCIE ranking: 7.7%)

  • [179]     Song-Ming Wang, 2009, “Searches for the Standard Model Higgs Boson at the CDF Experiment”, International Journal of Modern Physics A, Vol. 24, No. 4, 617-656. (SCIE) (IF: 1.291; SCIE ranking: 85%,89.7%)

  • [180]     T. Aaltonen et al., The CDF Collaboration, 2008, “Search for the Higgs Boson in Events with Missing Transverse Energy and b Quark Jets Produced in p anti-p Collisions at TeV”, Phys. Rev. Lett., 100, 211801. (SCIE) (IF: 8.839; SCIE ranking: 7.7%)

  • [181]     T. Aaltonen et al., The CDF Collaboration, 2007, “Searches for Direct Pair Production of Supersymmetric Top and Supersymmetric Bottom Quarks in Collisions at =1.96 TeV”, Phys. Rev. D, 76, 072010. (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [182]     A. Abulencia et al., The CDF Collaboration, 2006, “Measurement of the t anti-t Production Cross Section in p anti-p Collisions at sqrt(s)=1.96 TeV TeV using Lepton + Jets Events with Jet Probability b-tagging”, Phys. Rev. D, 74, 072006. (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

  • [183]     A. Abulencia et al., The CDF Collaboration, 2006, “Measurement of the tt-bar Production Cross Section in p anti-p Collisions at sqrt(s)=1.96 TeV”, Phys. Rev. Lett., 97, 082004. (SCIE) (IF: 8.839; SCIE ranking: 7.7%)

  • [184]     T. Aaltonen et al., the CDF Collaboration, 2005, “Search for scalar leptoquark pairs decaying to v(v)over-barq(q)over-bar in p(p)over-bar collisions at root s=1.96 TeV”, PHYSICAL REVIEW D, 71, 112001. (SCIE) (IF: 4.394; SCIE ranking: 24.1%,22.7%)

Technical Reports

  • [1]     ATLAS Collaboration, 2016, Search for a CP-odd Higgs boson decaying to $Zh$ in $pp$ collisions at $\sqrt{s}=13$ TeV with the ATLAS detector, 34 pages.

  • [2]     ATLAS Collaboration, 2016, Search for Higgs boson production via weak boson fusion and decaying to $b\bar{b}$ in association with a high-energy photon using the ATLAS detector, 18 pages.

  • [3]     ATLAS Collaboration, 2016, Search for the Standard Model Higgs boson produced in association with a vector boson and decaying to a $b\bar{b}$ pair in $pp$ collisions at 13 TeV using the ATLAS detector, 39 pages.

  • [4]     ATLAS Collaboration, 2015, Search for diboson resonances in the $\nu\nu qq$ final state in $pp$ collisions at $\sqrt{s} = 13$ TeV with the ATLAS detector, 20 pages.

  • [5]     ATLAS Collaboration, 2015, Search for new resonances decaying to a $W$ or $Z$ boson and a Higgs boson in the $llb\bar{b}$, $l\nu b \bar{b}$, and $\nu\nu b\bar{b}$ channels in $pp$ collisions at $\sqrt{s} = 13$ TeV with the ATLAS detector, 21 pages.

  • [6]     ATLAS Collaboration, Unpublished, “Combination of searches for invisible Higgs boson decays with the ATLAS experiment”, ATLAS-CONF-2018-054, pp. 11.

  • [7]     ATLAS Collaboration, Unpublished, “Measurement of , production as a function of the vector boson transverse momentum in 13 TeV collisions with the ATLAS detector”, ATLAS-CONF-2018-053, pp. 20.

發現與突破

(1) 西元年:2018
研究人員(中):王嵩銘、ATLAS Collaboration
研究人員(英):WANG, SONG-MING, ATLAS Collaboration
研究成果名稱(中):中研院物理所參與歐洲物理實驗 證實上帝粒子衰變為底夸克
研究成果名稱(英):Observation of Higgs boson decays to bb at the LHC
簡要記述(中):今(2018)年8月28日,歐洲核子研究組織(CERN)的ATLAS 團隊宣布此實驗已觀察到希格斯玻色子確實會衰變成一對底夸克(H→bb),證實了一套粒子物理的預測。中央研究院物理所王嵩銘副研究員領導的團隊,對此次重大發現有關鍵貢獻。
在粒子物理的標準模型中,希格斯玻色子負責產生基本粒子的質量。標準模型預測希格斯玻色子約有60%的機率會衰變為成一對底夸克,因此,科學家致力於探索H→bb這個衰變過程,希望進一步檢驗這套質量產生機制。
然而,在大型強子對撞機裡,要觀察到希格斯玻色子衰變成底夸克便非常困難,需要相當長的時間佐以大量的數據樣本。 王嵩銘副研究員表示:「這次探索是大型強子對撞機中最具挑戰性的分析之一。」為實現目標,ATLAS團隊分析了前二次運行期間所收集的數據樣本,並採用多變量分析算法等先進的分析技術,成功將H→bb信號與背景的底夸克隔離。分析結果已在Physics Letter B期刊發佈。
簡要記述(英):After six years since the discovery of the Higgs boson through the decays into gauge bosons (photon, W, Z), the ATLAS and CMS experiments at the LHC have finally observed the Higgs boson decaying into a pair of b-quarks (H→bb), which accounts for the largest fraction (about 58%) of all possible decays. Both experiments jointly announced this observation at a CERN seminar on August 28th [1], which was followed by a press release [2]. This observation is very important as it further strengthen the understanding of the mass generation mechanism predicted in the Standard Model (SM), and provides an additional confirmation of the “Yukawa-couplings” in which the charged fermion particles (leptons, quarks) acquire masses through coupling with the Higgs boson. The Taiwan Academia Sinica (AS) group is part of the team that contributes to the ATLAS’ observation result.

At ATLAS the H→bb signal is observed with a significance of 5.4 standard deviations. This result is obtained through analyzing the ATLAS Run 1 and Run 2 data samples (total integrated luminosity of about 100 fb-1) with the application of advanced techniques to extract the tiny signal in the data. To detect the signal several of its properties are exploited to separate the signal from the background. For example the long lifetime of the b-hadrons in the jets of the b-quarks from the Higgs decay, and the invariant mass resonance form by the two-b-jet system (see Figure 1). It takes a considerably longer time and larger data sample to observe the Higgs boson in this decay channel due to the overwhelming b-quark pair background that is produced via the strong interaction at the LHC. Thus making this search one of the most challenging analyses at the LHC. The ATLAS preliminary observation result [3] was first presented at the 2018 International Conference on High Energy Physics (ICHEP) at Seoul in July [4]. A paper was submitted on the same day as the joint CERN seminar to the Physics Letter B journal for publication [5]. This significant result is the outcome of the dedicated work of many physicists of the ATLAS collaboration and the fantastic performance of the LHC machine. A more general public explanation of this significant result can be found at [6].

The AS group has been active in the Higgs boson search via the H→bb decay channel for many years starting in the CDF experiment at the Tevatron and later continued the search in the ATLAS experiment since the beginning of the data taking by ATLAS at the LHC. The data analysis effort by the AS group is led by associate research fellow Song-Ming Wang. The AS team, including also the post-doctorial research Adrian Buzatu and PhD student Wei Wang, contributed significantly to the “0-lepton” sub-channel of this search. In this sub-channel the Higgs boson is produced in association with a Z boson and that the Z boson decays into a pair of neutrinos. The contributions from the AS team include:
• Improving the resolution of the measured two-b-jet system mass,
• Measuring the performance of the trigger used to collect the data for the “0-lepton” channel,
• Training the multivariate analysis algorithm to separate the H→bb signal from background,
• Development of the analysis software and performing the analysis.
Comparing among the sub-channels for this H→bb search, the 0-lepton sub-channel has one of the best sensitivity. Song-Ming Wang had also served as a co-convener of the ATLAS Higgs H→bb working group in 2015-2016.
(2) 西元年:2017
研究人員(中):王嵩銘、ATLAS Collaboration
研究人員(英):WANG, SONG-MING, ATLAS Collaboration
研究成果名稱(中):ATLAS實驗觀察到希格斯玻色子衰變到一對底夸克的證據
研究成果名稱(英):Evidence for Higgs decays to bb at ATLAS Experiment
簡要記述(中):希格斯玻色子(Higgs boson)在2012年被ATLAS和CMS實驗發現,當時的發現是透過規範玻色子衰變頻道。標準模型預測希格斯玻色子最常衰變為一對底夸克(H->bb,機率為~58%)。但是該頻道在LHC尚未被觀察到。 如果檢測到的H->bb衰變率與標準模型預測顯著不同則表示可能有新物理的跡象。
通過分析2015年和2016年收集的數據,ATLAS在希格斯玻色子與W或Z玻色子伴隨產生的模式中觀察到這種衰變 (H->bb) 模式的證據。這個證據的顯著性水平是3.5σ。為了檢測此搜索中的H->bb衰變,這個分析利用信號的幾個屬性將信號與背景分離。這個研究結過已發表在JHEP 12 (2017) 024 雜誌。 中央研究院(AS)於2011年加入ATLAS Hbb研究組,對微中子頻道(ZH->nunubb)作出了重大貢獻。該頻道是在這個搜索中使用的三個分析頻道之一。AS團隊一直積極參與此搜索。 AS-ATLAS團隊領導王嵩銘在2015-2016年擔任ATLAS Hbb研究組的聯合召集人。他也代表ATLAS實驗於2017/7/6在歐洲物理會議上首次公開了這項研究結果。
簡要記述(英):The Higgs boson was discovered in 2012 by the ATLAS and CMS experiments, in the gauge boson decay channels. Although according to the Standard Model (SM) Higgs decaying into a pair of b-quarks (H->bb) has the largest predicted decay branching fraction (BR~58%), this channel has not yet been observed at the LHC. If the detected H->bb decay rate differs significantly from the SM prediction, this could indicate a sign of new physics. Evidence of observing such decay mode was announced by ATLAS in July 2017, in the search channel where the Higgs boson is produced in association with a W or Z boson. To detect the H->bb decay in this search, several properties of the signal are exploited to separate the signal from the background. For example the long lifetime of the b hadrons in the jets of the b quark from the Higgs decay, and the invariant mass resonance form by the two-b-jet system. By analyzing the data sample collected with the ATLAS detector in 2015 and 2016, the first two years of LHC Run2 data taking, ATLAS found evidence for the H->bb decay at the significance level of 3.5 standard deviation. These results are published in JHEP 12 (2017) 024. Academia Sinica (AS) joined the ATLAS Hbb group in 2011 and made significant contributions to the neutrino decay channel (ZH->nunubb) that is characterized by large missing transverse energy. This channel is one of the three analyses channels employed in this evidence results. The AS group has continuously been an active participant in this search. Song-Ming Wang, leader of the AS-ATLAS team, had served as a co-convener of the ATLAS Hbb group in 2015-2016. He made the first public presentation of this evidence results on behalf of the ATLAS collaboration at the European Physical Society conference in Venice, Italy, on July 6th 2017.
Update Personal Data | Update Publication List | Synchronize | Last Updated: 2021-01-04
2
Back To Top