search for heavy neutral resonances in vector boson fusion in pp … · 2017. 10. 28. · search...

Search for heavy neutral resonances in vectorboson fusion in pp collisions at 𝒔𝒔 = 13 TeV

with the ATLAS detector at the LHC

October 27, 2017

Guangyi Zhang1,2

1University of Science and Technology of China2Institute of Physics, Academia Sinica

PhD thesis defense

Supervisor: Liang Han1, Suen Hou2

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Outline

Search for new resonances (R) in qq → Rqq → ℓ+𝜐𝜐ℓ-�̅�𝜐qq (ℓ = e, µ)

using 3.2 fb-1 data collected in 2015

Search for new resonances (X) in qq → Xqq → WWqq → e𝜐𝜐µ𝜐𝜐qq

using 36.1 fb-1 data collected in full 2015 and 2016

Introduction

Physics analyses

Summary

Standard model

Vector boson fusion

LHC and ATLAS detector

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Introduction

Electromagnetic force Weak force

Strong force Gravitation (not in the SM)4/48

Standard Model Standard Model (SM)• Most successful and well-tested theory

• Elementary particles: leptons, quraks (spin-½ fermions)

=> constituents of matter gauge bosons (W/Z, γ, g), spin-1

=> force mediators Higgs boson, spin-0

=> origin of mass

describing the elementary particles and their interactions

• Fundamental forces: electromagnetic, weak, strong forces gravitation not described in the SM

• Origin of mass: Higgs Mechanism, EWSB particles acquire mass via interactions

with Higgs field (υ ≠ 0)

nb

JHEP: 0811.010 (2008)

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Vector boson fusion In the SM, vector boson fusion (VBF) is an important class of processes

• provide a unique means to directly examine the EWSB mechanism

W+W- scattering/fusion without a SM Higgs

W+W- scattering/fusion with a SM Higgs

nb

JHEP: 0811.010 (2008)

unitarity violated

unitarity restored

“u” Mandelstam variable

+

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Vector boson fusion VBF is very sensitive to phenomena beyond the SM

?

• Unknown issues about Higgs boson discovered at the LHC:

fully or only partially unitarizes the VBF amplitude ?

is the coupling H→VV exactly the one that SM predicted ?

(low measurement precision ~20 %)

• New resonance needed:

Higgs partially unitarizes the VBF amplitude => new resonances

Any non-SM HVV coupling => new physics

If new resonance has no/weak coupling to fermions

=> VBF is a leading search channel

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Vector boson fusion Characteristics of VBF

• Relatively small production cross sections

=> Experimental studies of VBF are feasible only at the LHC so far

• Fully-leptonic channels have lower SM background

=> Considered in the analyses

• VBF event topology at the LHC

two charged leptons (ee, μμ, eμ), 𝐸𝐸𝑇𝑇𝑚𝑚𝑚𝑚𝑚𝑚𝑚𝑚, two forward jets (tagging jets)

VBF signal characteristics:

Large mjj (>500 GeV)

Large Δηjj (>2.4)

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Large Hadron Collider (LHC)

proton-proton (pp) collisions• World’s largest and most powerful particle accelerator

• Purpose: Higgs boson, new physics (eg. dark matter ), etc.

• Two separate rings: 26.7 km, 45-175m underground

• Four major detectors: ATLAS, CMS, ALICE and LHCb

• pp collisions: 2835×2835 bunches, bunch spacing

25 ns (7.5 m), 1011 protons/bunch

• Designed luminosity and center-of-mass energy:

ℒ = 1034𝑐𝑐𝑐𝑐−2𝑠𝑠−1, 𝑠𝑠 =13 TeV (2015-2018), 14 TeV (2021-2037)

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ATLAS detector

44 m

25 m

7000 t

ATLAS detector: a general purpose detector at the LHC

Muon spectrometer (|η|<2.7)-precise tracking and triggering on muons-precision-tracking systems: MDT, CSC-trigger systems: RPC, TGC

Inner detector (|η|<2.5):- precise measurement of trackingand vertices

- Pixel, SCT, TRT

EM calorimeter (|η|<3.2):-e/γ measurement-LAr-Pb accordion

Magnet system:-solenoid magnet (barrel), 2 T-toroid magnets, 0.5 T (barrel), 1 T (end-cap)

HAD calorimeter (|η|<4.9):-hadronic measurements-scintillating tiles-steel (central), LAr-Cu/tungsten (forward)

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Search for new resonances (R) inqq → Rqq → ℓ+𝜐𝜐ℓ-�𝝊𝝊qq (ℓ = e, µ)using 3.2 fb-1 data collected in 2015

ATLAS conference note: ATLAS-CONF-2016-053

Proceeding paper: EPJ Web of Conferences 137, 08016 (2017)

My contributions: All physics analysis work

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Introduction Analysis goal:

• Search for new resonances (R) in VBF qq → Rqq → ℓ+𝜐𝜐ℓ-�̅�𝜐qq (ℓ = e, µ)three decay channels: ee, μμ, eμ

Signal model:

Γ0=g2m3/64πυ2

σ: scalar isoscalarφ: scalar isotensorρ: vector isovectorf: tensor isoscalart: tensor isotensor

• Benchmark model: EW chiral Lagrangian (EWChL) with K-matrix unitarization• New resonances: only couples to vector boson, thus mainly produced via VBF• Free parameters: coupling RVV (g=2.5) & mass [200, 500] GeV

scalar

vector

tensor

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Signal Signal definition:

Signal sample

• New resonance

• SM EW qq→ℓ+𝑣𝑣ℓ-�̅�𝑣qq

• Interference

SM continuumsample

• SM EW qq→ℓ+𝑣𝑣ℓ-�̅�𝑣qq

= Signal (New resonance + interference)

Signal Xsec vs. resonance mass

-

Using Whizard+Pythia8 to generate both samples

SM EW continuum

Signal samples

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Data/MC samples Data samples:

• 25 ns data in 2015, Luminosity = 3.2 fb−1

MC corrections:

• Lepton energy/momemtum scale/resolution• Lepton Reco/ID/Iso/Trig effSF• Jet energy scale/resolution, b−tag effSF• Pile-up reweighting

MC samples:

• 𝑡𝑡 ̅𝑡𝑡: Powheg• Wt: Powheg• Z+jets: MadGraph (QCD) and Sherpa (EW)• diboson: Sherpa (QCD) and Whizard (EW)• Zγ: Sherpa • ttV: MadGraph• SM Higgs: Powheg (ggH and VBF)

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Event selection Event selections for signal region (SR):

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Background estimation

• W+jets• QCD

• Z+jets

• 𝑡𝑡 ̅𝑡𝑡• Wt• ttV• Zγ+jets• diboson (WW/WZ/ZZ)• SM Higgs (ggH, VBF)Backgrouds of

ll'+ETmiss+2jets

SM processes that can produce events with

two OS leptons

SM processes that haveone or two leptons from

jets (faked)

MC prediction

Data driven(Matrix method)

Strategy of background estimation:

Validation regions (VRs) :

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Dominant background sources :• For ee/μμ channel: Z+jets & 𝑡𝑡 ̅𝑡𝑡• For eμ channel: 𝑡𝑡 ̅𝑡𝑡

Background estimation

• Selection criteria listed on slide 14 is assumed unless otherwise specified

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Z pT reweighting for the Z+jets prediction:

• Some discrepancy is found between data & MC for Z pT distribution • Reweighing function is derived by using a polynomial fit for the spectrum

(Data-Non-Z+jets) /Z+jets• Cut 1-9 in slide 14, |mℓℓ-mZ| < 25 GeV• This reweighting function used in both VRs and SR

Reweighting fit function Before reweighting After reweighting

Data vs. prediction in Z+jets VR

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Data vs. prediction in Z+jets VR Z+jets VR: |mℓℓ-mZ| < 25 GeV, no mjj cut

Reasonable agreement of data and the SM prediction observed in Z+jets VR

MTWW

Njets

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Data vs. prediction in 𝒕𝒕�̅�𝒕 VR 𝑡𝑡 ̅𝑡𝑡 VR: Nb-jets > 1, no mjj cut

Good agreement of data and the SM prediction observed in 𝑡𝑡 ̅𝑡𝑡 VR

MTWW

Nb-jets

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Fake background estimation (matrix method)Matrix Method: a data-driven method to estimate fraction of jets misidentified as leptons.

Relation for the event numbers in the different subsamples:

• r1, r2 (f1, f2): the real (fake) rates evaluated for leading(1) and sub-leading(2) leptons

Fake contribution estimation:

• Measure the real rate of electron: tag-probe method is used to extract it from di-el data sample

• Measure the fake rate of electron: obtained from a fake enriched data sample, MC subtraction.

• Measure NTL, NLT, NTT, NLL, then invert the matrix to get the fake contribution--NRF, NFR, NFF

• The matrix method is applied event by event

This matrix method depends on two parameters:

• Real rate: probability for a real lepton identified as a loose lepton to pass tight lepton selection;

• Fake rate: probability for a real jet identified as a loose lepton to pass tight lepton selection.

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Fake background estimation (matrix method) Real rate of electron vs. el_pt, el_η:

Real rate

Fake rate

Fake rate of electron vs. el_pt, el_η:pT η

pT η

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Data vs. prediction in low-mjj VR

Reasonable agreement of data and the SM prediction observed in low-mjj VR

low-mjj VR: mjj < 500 GeV, validate the overall background estimation

MTWW

mjj

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Data vs. prediction in the signal region Signal region (SR):

• Based on all selections on slide 14

No significant data excess above the SM background prediction is observed in SR

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Data vs. prediction in the signal regionee-channel µµ-channel

eµ-channel

-- Due to two neutrinos in the final state,

𝑀𝑀𝑇𝑇𝑊𝑊𝑊𝑊 is a useful discriminating variable:

-- No significant excess beyond the SM

background predication is found

MTWW

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Systematic uncertainties Experimental uncertainties(%) on the backgrounds in the signal region:

Theoretical uncertainties on the production Xsec of the backgrounds

Additional shape systematic uncertainties for two dominant backgrounds

(Z+jets, 𝑡𝑡 ̅𝑡𝑡) are included.

Experimental uncertainties on signal considered (JES/JER, b-tagging, 𝐸𝐸𝑇𝑇𝑚𝑚𝑚𝑚𝑚𝑚𝑚𝑚etc.)

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95% CL upper limits

σ

No significant excess above the SM background expectation is observed.

95% CL upper limits are derived on σ×Br for new resonances (σ, φ, ρ, f and t)

Number counting as inputs to set limit due to limited signal statistics

The frequentist method (CLs), is used to compute 95% CL upper limits

ρ

φ

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95% CL upper limits f

t Observed 95% CL exclusion limitsin 200-500 GeV mass region:

380 − 220 fb (σ particle)460 − 240 fb (φ particle)330 − 270 fb (ρ particle)340 − 260 fb (f particle)310 − 260 fb (t particle)

mR < 230 (300) GeV for ρ (f) excluded

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Summary for analysis 1

• SM backgrounds are carefully studied using MC simulation and

data-driven (matrix method) and validated in several VRs.

• all the possible uncertainties are well evaluated

• no significant data excess above the SM prediction is observed

• First 95% CL upper limits derived, mR < 230 (300) GeV for ρ (f) resonance excluded

Search for new resonances (R) in qq → Rqq → ℓ+𝜐𝜐ℓ-�̅�𝜐qq (ℓ = e, µ) using 3.2 fb-1 data

Need to update:

• Published on:

EPJ Web of Conferences 137, 08016 (2017)

ATLAS-CONF-2016-053

• Small data set (3.2 fb-1)

• Signal samples – low statistics

• Three decay channels (ee, μμ, eμ) studied, but the most sensitive one is eμ

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Search for new resonances (X) inqq → Xqq → WWqq → e𝜐𝜐µ𝜐𝜐qqusing 36.1 fb-1 data (2015+2016)

Paper: submitted to Eur. Phys. J. C, arXiv:1710.01123 [hep-ex]

CERN Preprint URL: CERN-EP-2017-214

My contributions: signal Monte Carlo samples generation, signal

acceptance and predictions, event selection optimization, systematic

uncertainties, etc.

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Introduction Analysis goal:

• Search for new resonances (X) in VBF qq → Xqq → WWqq → e𝜐𝜐µ𝜐𝜐qq

Main differences with the previous analysis:

• Data: 3.2 fb-1 in 2015 => 36.1 fb-1 in full 2015+2016

• Signal model: EWChL model => several individual signal models covering scalar,

vector and tensor resonances

• Signal mass range: extended from 500 GeV up to 3000 GeV

• Decay channel: ee, μμ, eμ => eμ (most sensitive one and easier to handle the SM bkg)

• Event categories: VBF Njet ≥ 2 => VBF Njet ≥ 2 + VBF Njet =1 (gain more sensitivities)

• Event selection and background estimation: optimized and updated accordingly

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Signal models Signal models: new scalar, vector and tensor resonances introduced

• Heavy Higgs with a Narrow Width Approximation (NWA, scalar)

• Heavy Higgs with a Large Width Assumption (LWA, scalar)

• Georgi-Machacek (GM, scalar) model

width = 4 MeV (same widths for different heavy Higgs masses) mass = [200, 3000] GeV

width = 5%, 10% and 15% of heavy Higgs mass mass = [200, 3000] GeV

new scalar resonance: 𝐻𝐻50 (does not couple to fermions) parameters:

o 𝐻𝐻50𝑉𝑉𝑉𝑉 coupling, proportional to 𝑠𝑠𝑠𝑠𝑠𝑠𝜃𝜃𝐻𝐻 (= 0.4)o mass = [200, 1000] GeV

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Signal models• Heavy Vector Triplet (HVT, vector) model new vector resonance: 𝑍𝑍′ parameters:

o 𝑍𝑍′VV coupling 𝑔𝑔𝑉𝑉 (=1)o mass = [300, 1000] GeVo to suppress the non-VBF contributions, assume that 𝑍𝑍′ bosons

does not couple to fermions

• Effective Lagrangian Model (ELM, tensor)

new tensor resonance (spin-2): T parameters:o TVV coupling 𝑓𝑓𝑚𝑚 (=1)o mass = [200, 1000] GeVo T resonance doesn’t couple to fermions

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Event selection Event selections for signal regions (VBF Njet = 1 SR, VBF Njet ≥ 2 SR)

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Background estimation Backgrounds:

• Top and WW (dominant backgrounds):

Normalization factors obtained from simultaneously fitting top and WW contributions to data in control and signal regions

• W+jets: data driven method - “fake-factor” method

• Z+jets, non-WW diboson, Higgs production: small contribution, MC simulation

Background estimation

• Top, WW, non-WW diboson, Z+jets, W+jets, Higgs production

WW in VBF 2J category which was from MC prediction(small contribution, diffcult to isolate a kinematic region with high purity of WW)

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Control regions Definition of Top and WW control regions (CRs)

• some cuts inverted, removed or loosened to gain more data

statistics and higher purity

WW background:

• VBF Njet = 1: WW CR• VBF Njet ≥ 2: WW MC simulation

Top background:

• Top CR: combined VBF Njet = 1and VBF Njet ≥ 2 to gain morestatistics

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Data vs. prediction in the control regions Top control region:

WW control region:

NF_Top_VBF = 1.12−0.12+0.13

NF_WW_VBF1J =1.0 ± 0.2

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W+jets estimationW+jets estimation

• use a data-driven method - “fake factor method” to estimate its contribution

• two basic components: W+jets control sample and the fake factor

W+jets control sample (𝑁𝑁id+anti−id):

o selected from the data using the same event selections as SR but requiringone pair of id+anti-id leptons

o non-W+jets contributions (eg. Top and WW) 𝑁𝑁id+anti−idEW subtracted using MC

2.5

W+jets control sample fake factor

barrel end-cap

barrel end-cap

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W+jets estimationW+jets estimation

fake factor ( 𝑁𝑁idNanti−id

):

o measured using a fake-enriched dijet data sample, with EW (W/Z+jets) subtraction o small trigger bias also considered (more in backup)

Electron

Muon

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Data vs. prediction in the signal region Signal region:

No significant data excess above the SM background prediction observed

VBF 1J SR VBF 2J SR

mT

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Systematic uncertainties Uncertainties of Top background (%):

• Only dominant uncer. shown, others included in “Total”• Single top: theoretical uncer. on single-top-quark production

Uncertainties of WW background (%):• Only dominant uncer. shown, others included in “Total”

Shape uncertainties of Top and WW:• mT shape dependence for the PDF uncertainty in the SRs considered

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Systematic uncertainties Uncertainties of W+jets background:

• mainly arise from jet flavor composition, EW subtraction, stat. uncertainty, etc.

• VBF 1J SR: 32%, VBF 2J SR: 35%

Uncertainties of signal (NWA):

• mainly arise from parton shower, PDF, QCD scales, etc.

• VBF 1J SR: 5.1% - 9.0%, VBF 2J SR: 3.3% - 8%

Uncertainties of other background:

• smaller contributions on the uncertainties

• experimental uncertainties, normalized to high-order Xsec. prediction

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95% CL upper limits No data excess above the SM prediction is observed. 95% CL upper limits are derived on σX×Br(X→WW) The frequentist method (CLs), is used to compute 95% CL upper limits

NWA LWA

GMValues above 1.3 pb at 200 GeV

and above 0.006 pb at 3 TeV for

NWA and 15% LWA are excluded

Scalar resonances

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95% CL upper limits

Current sensitivity not sufficient to exclude the VBF signals from

GM, HVT and ELM models

HVT ELM

Vector resonance Tensor resonance

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Summary for analysis 2

• SM backgrounds are carefully studied using simultaneous fit, fake factor

method and MC simulation, and validated in specific CRs.

• all the possible uncertainties are properly evaluated

• no evidence of such heavy neutral resonances is found

• 95% CL upper limits set on σX×Br(X→WW) of new scalar, vector and tensor

resonances predicted by several individual signal models

Search for new resonances (X) in qq → Xqq → WWqq → e𝜐𝜐µ𝜐𝜐qq using 36.1 fb-1 data

• Published on:

Eur. Phys. J. C, arXiv:1710.01123 [hep-ex] (submitted)

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ATLAS MDT gas work (install, repair and maintain) MDT (Monitored Drift Tubes) gas system repairs and maintenance:

Installation of MDT gas system for BME chambers:

Obtained the ATLAS authorship and took a lot of shift work assigned to USTC

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Publications Publications

• “Search for heavy resonances decaying into WW in the e𝜐𝜐μ𝜐𝜐 final state in pp collisions at 𝑠𝑠 = 13 TeV with the ATLAS detector”Submitted to Eur. Phys. J. C, arXiv:1710.01123 [hep-ex]

• “Search for heavy resonances in vector boson fusion”EPJ Web of Conferences 137, 08016 (2017)

• “Search for heavy neutral resonances in vector boson fusion in pp collisions at𝑠𝑠 = 13 TeV with the ATLAS detector at the Large Hadron Collider”

ATLAS-CONF-2016-053

• “Multi-Boson Simulation for 13 TeV ATLAS Analyses”ATL-PHYS-PUB-2017-005

Paper in ATLAS EB review• “Measurement of 𝑍𝑍𝑍𝑍 → ℓ+ℓ−𝜐𝜐�̅�𝜐 production in proton-proton collisions at 𝑠𝑠 =

13 TeV with ATLAS detector”ATL-COM-PHYS-2016-1801 (aim at Eur. Phys. J. C)

• “Search for heavy resonances in vector boson fusion at 𝑠𝑠 = 13 TeV with theATLAS detector at the LHC”, The 9th Joint Meeting of Chinese PhysicistsWorldwide, Tsinghua University, Beijing, China, 17-20 July, 2017http://meetings.csp.escience.cn/dct/page/1(2017 APS-OCPA Outstanding Conference Poster Award) 47/48

Conference talks and posters Conference talks

• “Search for heavy resonances in vector boson scattering”, XII Quark Confinement and the Hadron Spectrum, Thessaloniki, Greece, Aug. 29 - Sep. 03, 2016.https://indico.cern.ch/event/353906/contributions/2257680/

• “VBF/VBS Resonances”, ATLAS Beyond the Standard Model Higgs and Exotics Joint Workshop, Grenoble, France, 11-15 April, 2016.https://indico.cern.ch/event/465157/

• “Search for heavy neutral resonances in vector boson fusion qq → ℓ𝜐𝜐ℓ𝜐𝜐qq with the ATLAS detector”, Second China LHC Physics Workshop, Peking University,Beijing, China, 16-19 December, 2016http://indico.ihep.ac.cn/event/6062/contribution/66

Conference posters

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Summary

• Search for new resonances (R) in qq → Rqq → ℓ+𝜐𝜐ℓ-�̅�𝜐qq (ℓ = e, µ)

using 3.2 fb-1 data collected in 2015

• Search for new resonances (X) in qq → Xqq → WWqq → e𝜐𝜐µ𝜐𝜐qq

using 36.1 fb-1 data collected in full 2015 and 2016

Two physics analyses performed using pp collision data recoded at

𝑠𝑠 = 13 TeV with the ATLAS detector at the LHC

4 publications, 1 paper under ATLAS review, 3 conference talks,

1 conference poster (outstanding award)

and many important ATLAS group talks (eg. unblinding & approval talks)

ATLAS MDT gas system installation, repair and maintence

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Backup

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Mandelstam variables (analysis 1) Definitions of Mandelstam variables (s, t, u)

• 𝑠𝑠 ≈ 2𝑝𝑝1 � 𝑝𝑝2 ≈ 2𝑝𝑝3 � 𝑝𝑝4• 𝑡𝑡 ≈ −2𝑝𝑝1 � 𝑝𝑝3 ≈ −2𝑝𝑝2 � 𝑝𝑝4• 𝑢𝑢 ≈ −2𝑝𝑝1 � 𝑝𝑝4 ≈ −2𝑝𝑝3 � 𝑝𝑝2

s-channel

t-channel

u-channel

Relativistic limit (large p)

• 𝐸𝐸2 = 𝐩𝐩 � 𝐩𝐩 + 𝑐𝑐02 ⇒ 𝐸𝐸2 ≈ 𝐩𝐩 � 𝐩𝐩

⇒ 𝑠𝑠 = (𝑝𝑝1 + 𝑝𝑝2)2= 𝑝𝑝12 + 𝑝𝑝22 + 2𝑝𝑝1 � 𝑝𝑝2≈ 2𝑝𝑝1 � 𝑝𝑝2

where 𝑝𝑝12 = 𝑐𝑐12, 𝑝𝑝22 = 𝑐𝑐2

2

• 𝑠𝑠 = (𝑝𝑝1 + 𝑝𝑝2)2=(𝑝𝑝3 + 𝑝𝑝4)2

• 𝑡𝑡 = (𝑝𝑝1 − 𝑝𝑝3)2=(𝑝𝑝4 − 𝑝𝑝2)2

• 𝑢𝑢 = (𝑝𝑝1 − 𝑝𝑝4)2=(𝑝𝑝3 − 𝑝𝑝2)2

51

Feynman diagrams of VBF (analysis 1) NonVBF-EW process

VBF-QCD process

52

Effective theories and Unitarity (analysis 1)

53

Adding a resonance (analysis 1)

K-matrix

54

K-matrix unitarization (analysis 1)

55

K-matrix unitarization (analysis 1)

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Object definition (analysis 1)Selection Electron MuonpT (GeV) >25 >25|η| <2.47, veto 1.37-1.52 <2.5| d0/σ(d0) | <5 <3| z0 sinθ | (mm) <0.5 <0.5ID TightLH (if Et_el<300 GeV)

MediumLH(if Et_el>300 GeV)Medium

Isolation passTightIso passTightIso

Selection JetJet type AntiKt4EMTopoJets

pT (GeV) >30(>50 if 2.5<|η|<4.5)

|η| <4.5

JVT JVT > 0.64 if |η| < 2.4 and pT < 50 GeV

Jet quality Not badjet

Jet flavor tagger MV2c20 (85% efficiency)

Selection METMETContainer MET_Reference_Anti

Kt4EMTopoObjets used to rebuild MET

Electrons, muons, jets

METSoftTerm Track soft terms

MET(GeV) >35

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Triggers and signal acceptance (analysis 1) Single-lepton triggers:

Signal acceptance times efficiency:

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Lepton centrality and frecoil (analysis 1) Lepton centrality ζ :

frecoil:

• Measures the strength of the recoil system relative to the dilepton system

• ϛ in VBF topology tends to be positive

• To reduce the background from strongproduction of double vector boson processes(ϛ > -0.5)

•

• Useful to reject the Z/γ* → ℓℓ background• frecoil < 2

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Real rate of electron (analysis 1)

Selection Tight Electron Loose ElectronpT (GeV) >25 >25|η| <2.47, veto 1.37-1.52 <2.47, veto 1.37-1.52| d0/σ(d0) | <5 <5| z0 sinθ | (mm) <0.5 <0.5ID TightLH

(MediumLH, if Et_el>300GeV)LooseLH

Isolation passTightIso No isolation requirement

Tight/Loose electron definitions:

Cut flow:• Basic event pre-selection, event cleaning/GRL cut/PV cut.

• Single-electron trigger chain(e24_lhmedium_L1EM20VH || e60_lhmedium || e120_lhloose)

• Exactly two LOOSE electrons with opposite sign

• mZ -10GeV < mee < mZ +10GeV

• At least one Tight lepton as Tag

• For the probe lepton, real rate = NTight/NLoose

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Fake rate of electron (analysis 1)

Selection Tight Electron Loose ElectronpT (GeV) >25 >25|η| <2.47, veto 1.37-1.52 <2.47, veto 1.37-1.52| d0/σ(d0) | <5 <5| z0 sinθ | (mm) <0.5 <0.5ID TightLH

(MediumLH, if Et_el>300GeV)LooseLH

Isolation passTightIso No isolation requirement

Tight/Loose electron definitions:

Cut flow:• Basic event pre-selection, event cleaning/GRL cut/PV cut.

• use single-electron trigger chain (e24_lhloose_L1EM20VH || e60 _lhloose || e120_lhloose)

• At least one LOOSE electrons

• reject events with two loose electrons in Z mass window(|Mee-MZ|<20GeV)

• reject events with two or more tight electrons

• MET<25GeV

• Fill histrograms, fake rate = NTight/NLoose

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Signal models (analysis 2) Signal models: new scalar, vector and tensor resonances introduced

• Heavy Higgs with a Narrow Width Approximation (NWA)

• Heavy Higgs with a Large Width Assumption (LWA)

• Georgi-Machacek (GM) model

width = 4 MeV (same widths for different heavy Higgs masses) mass = [200, 3000] GeV

width = 5%, 10% and 15% of heavy Higgs mass Mass = [200, 3000] GeV

extend Higgs sector with additional one real and one complex triplets scalar potential determined to keep the ratio of charged to neutral currents as

in SM (ρ parameter = 1)

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• Georgi-Machacek (GM) model reorganize the physical states to have

• 2 singlet neutrals (ℎ,𝐻𝐻)• triplet (𝐻𝐻3+,𝐻𝐻30,𝐻𝐻3−)• fiveplet (𝐻𝐻5++,𝐻𝐻5+,𝐻𝐻50,𝐻𝐻5−,𝐻𝐻5−−)

parameters• All the H5VV couplings are proportional to 𝑠𝑠𝑠𝑠𝑠𝑠𝜃𝜃𝐻𝐻 (fraction of the gauge

boson masses 𝑐𝑐𝑊𝑊 and 𝑐𝑐𝑍𝑍 generated by the vev of the triplets)• resonance mass: [200, 1000] GeV• H5 scalars does not couple to fermions

• Heavy Vector Triplet (HVT) model parameterizes the couplings of the HVT bosons to the SM gauge bosons and

Higgs with 𝑐𝑐ℎ𝑔𝑔𝑉𝑉, to the fermions with 𝑔𝑔2𝑐𝑐𝐹𝐹/𝑔𝑔𝑉𝑉 new resonances (𝑍𝑍′, 𝑊𝑊′) parameters

• XVV coupling 𝑔𝑔𝑉𝑉 (=1), resonance mass [300, 1000] GeV• to suppress the non-VBF contributions, assume that HVT bosons

does not couple to fermions (𝑐𝑐𝐹𝐹=0)

Signal models (analysis 2)

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• An an effective Lagrangian model (ELM)

introduce general spin-2 fields 𝑇𝑇𝜇𝜇𝜇𝜇 (singlet) and 𝑇𝑇𝑗𝑗𝜇𝜇𝜇𝜇(triplet)

spin-2 singlet case considered, its effective Lagrangian

a form factor introduced to multiply with the amplitudes topreserve unitarization

parameters• characteristic energy scale: Λ = 1.5 TeV• cut-off energy scale and suppression power: Λ𝑓𝑓𝑓𝑓 = 3 TeV, 𝑠𝑠𝑓𝑓𝑓𝑓 = 4• variable coupling parameters: 𝑓𝑓1 = 𝑓𝑓2 = 𝑓𝑓5 = 1• resonance mass: [200, 1000] GeV• Spin-2 resonances doesn’t couple to fermions

Signal models (analysis 2)

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GM model (analysis 2)https://cds.cern.ch/record/2002500/files/LHCHXSWG-2015-001_2.pdf

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GM model (analysis 2)https://cds.cern.ch/record/2002500/files/LHCHXSWG-2015-001_2.pdf

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HVT Model (analysis 2)https://arxiv.org/pdf/1402.4431.pdf

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Spin-2 Model (analysis 2)https://arxiv.org/pdf/1211.3658.pdf

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Spin-2 Model (analysis 2)https://arxiv.org/pdf/1211.3658.pdf

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Triggers and mT definition (analysis 2) Nominal triggers

Triggers for selecting dijet sample in W+jets estimation

mT definition

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Data/MC sample for analysis 2 Data samples:

• Full data in 2015+2016, Luminosity = 36.5 fb−1

MC samples:

• Signal samples

NWA: Powheg + Pythia8 LWA: MG5_aMC@Nlo + Pythia8 GM/HVT: MG5_aMC@Nlo + Pythia8 ELM: VBFNLO + Pythia8

• Background samples

Top: Powheg + Pythia8 WW: Sherpa 2.2.1 Non-WW diboson: Sherpa 2.2.1 Z+jets: Sherpa 2.1.1 Higgs: Powheg + Pythia8

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Signal acceptance times efficiency (analysis 2)

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W+jets estimation (analysis 2)

• selected using the single-lepton prescaled triggers with the low-pT

thresholds of 12 (14) GeV for electrons (muons)

Dijet sample for fake factor measurement:

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W+jets estimation - trigger bias (analysis 2) A small trigger bias:

• Introduced when the anti-lepton fires the triggers while the id leptondoes not fire the triggers.

• Triggered fake factor:using the nominal unprescaled single-lepton triggers to select dijet sample

Nominal fake factor: applied to the most of events (92%) in the W+jets control sample

Triggered fake factor: only applied to the events (8%) where the anti-lepton fires the triggers and the id lepton does not fire the triggers.

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W+jets estimation - CR (analysis 2) VBF 1J category

VBF 2J category

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W+jets estimation (analysis 2)

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W+jets estimation (analysis 2)

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mT shape uncertainties of Top and WW (analysis 2)

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mT shape uncertainties of NWA signal (analysis 2)

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Correlations among nuisance parameters (analysis 2) NWA m = 800 GeV:

correlation coefficients > 0.4 are shown

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ATLAS MDT gas system work Off-detector MDT gas system

• Supplies a steady gas flow

• Baseline of MDT gas mixture:

Ar ~93%, CO2 ~ 7%, H2O~0.075%

• Chamber volume: ~725000 nl

• Operating pressure: 3 bar

• Running in a loop, driven by a pump

• Fresh gas input is 10% per day,

10% of gas is flushed per day.

• 15 distribution racks , each one

contains 16 ~ 24 gas channels

• Controlled by GCS.https://atlasop.cern.ch/twiki/bin/view/Main/MDTGasSystemOverview

Off-detector MDT gas system

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ATLAS MDT gas system work On-detector MDT gas system

https://atlasop.cern.ch/twiki/bin/view/Main/MDTGasSystemOverview

On-detector MDT gas system

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ATLAS MDT gas system workMDT leak measurement

Leak rate = 104 mbar/d

Procedure:

-- Rack channel closed-- Measuring temperature

and pressure-- Calculating temperature

corrected pressure (normalized to Tn=20℃)

Calculating gas loss usingp1V0/T1=pnVn/Tn

-- p1 : measured (uncorr.) pressure-- V0: channel gas volume-- T1: measured temperature-- Vn: norm volume(3*V0)-- Tn: norm temperature(293K)-- Pn: derived normalized

pressure

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ATLAS MDT gas system workMDT EO gas leak repairs (2014-2015)

2015

2014

EO gas leaks improved a lot.

1: gas-jumpers made of NORYL (old), 2 : gas-jumper made of POCAN (new)

EO A side:Philipp Fleischmann, Guangyi ZhangEO C side:Anatoli Kozhin ,Vladimir Gushchin

In the most case, gas leaks ofEO are caused by cracks of gasjumpers made of NORYL

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ATLAS MDT gas system workMDT Barrel gas leak repairs (2014-2015)

BOL5A01_ML2BOL2A03_ML1BIS6C14_ML1

MDT Barrel gas leak measurement (2014-2017)

BME4A13_ML1 BMF2A14_ML1 EIL2A11_ML2 BIL4A01 ML1

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ATLAS MDT gas system workMDT EO gas leak measurement and repairs (2016-2017)

Gas connections and leak measurement for all new MDT BMG chambers (2017):

Before repairs(2016)

After repairs(2017)

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Data taking

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LHC / HL-LHC Plan