Physics at the LHC: from Standard Model to new discoveries

Physics at the LHC: from Standard Model to new discoveries Kirill Melnikov University of Hawaii May 2006 Sendai, June 2006 Physics at the LHC: from Standard Model to new discoveries p. 1/22

Outline Standard Model LHC Higgs boson at the LHC Beyond the Higgs boson Conclusion Physics at the LHC: from Standard Model to new discoveries p. 2/22

The Standard Model The Standard Model: relativistic quantum renormalizable field theory; gauge group SU(3)C SU(2) L U(1) R. Particle content: leptons: e, µ, τ; νe, ν µ, ν τ. quarks: u, c, t; d, s, b. bosons: g, γ, Z, W ; H. All the particles but the Higgs boson H have been found. As a matter of principle, every fact that exists in sciences derives from the Standard Model. The Standard Model, as we know it, can not be the final theory; gravity is not included. Physics at the LHC: from Standard Model to new discoveries p. 3/22

Experimental tests Collider tests: E = mc 2 : produce new (heavy) particles by increasing the energy of the colliding objects LEP, Tevatron, LHC, ILC(?) Precision tests: t E : quantum fluctuations lead to testable imprints. magnetic and dipole moments of elementary fermions, muon decay, atomic parity violation, CP-violation, flavor violation µ eγ. The SM has been tested through energies 100 GeV or distances 10 18 m. No sizable deviations from the Standard Model predictions found so far. Most of the facts that do not fit into the Standard Model come from cosmology/astroparticle physics: dark matter; dark energy; baryon asymmetry; neutrino masses. To accomodate those facts, modifications of the Standard Model are required. Physics at the LHC: from Standard Model to new discoveries p. 4/22

Modifications of the Standard Model Empirical approach: minimal modifications to accomodate established facts; keep renormalizability as the guiding principle for building the theory; Aesthetic approach: forget about the rules of the game in the renormalizable quantum field theory ask Why? Why is gravity so weak? MPlanck 1 TeV Why the Higgs boson mass is stable against radiative corrections? Why are neutrino masses so close to the dark energy scale? extra dimensions, little Higgs, Higgsless models, landscape, variations of the above. supersymmetric extensions of the SM. To find the Higgs boson and to search for beyond the Standard Model physics, the Large Hadron Collider (LHC) is being built. Physics at the LHC: from Standard Model to new discoveries p. 5/22

The LHC will find something Solid argument: either the SM Higgs boson is found at the LHC or something unexpected happens: If mh < 1 TeV, the LHC will see the Higgs; If mh > 1 TeV, the interaction of electroweak gauge bosons in the SM becomes strong at around 1 TeV. Less solid argument: hierarchy/naturallness problem. It is not natural that the SM with the light Higgs boson is a valid theory up to an arbitrary large scale. Assume SM is only valid up to a cut-off Λ 10 TeV: m 2 H = m2 tree 3λ2 t Λ2 8π 2 +... = m 2 tree 100[200 GeV] 2. To have m 2 H (200 GeV) 2, a tuning of about 10 2 is required in m 2 tree. The hierarchy/naturallness problem is solved in BSM models by introducing new forms of matter with mass about few TeV such particles will be, generically, found at the LHC. Physics at the LHC: from Standard Model to new discoveries p. 6/22

The LHC The LHC parameters: proton beams collision energy 14 TeV 7 Tevatron luminosity 10 fb 1 100 Tevatron Two major all purpose detectors: ATLAS and CMS. Increase in energy and luminosity leads to very high rates for SM processes Process σ (nb) evts/s Jets, E T > 0.1 (2) TeV 10 3 (10 4 ) W ± eν e 20 c c, b b 8 10 6, 5 10 5 t t 0.8 A machine with unique potential and unique challenges. Physics at the LHC: from Standard Model to new discoveries p. 7/22

The LHC: challenges Hadron collider: non-perturbative dynamics: Factorization theorems universal non-perturbative input; Asymptotic freedom applicability of perturbation theory; σ = D σ pert F P 1 P 2 x 1 P 1 x 2 P 2 F parton distribution function; data; D fragmentation models; data; σpert hard scattering cross-section; theory. Fixed order perturbation theory often insufficient. Physics at the LHC: from Standard Model to new discoveries p. 8/22

The LHC: challenges dσ / dp t Z (pb/gev) All orders treatment of QCD non-trivial: Perturbation theory shower event generators ; Shower event generators hadronization models; Hadronization models detector response simulation. 30 25 20 15 10 5 experimental data k t = 2 GeV, Λ QCD = 0.19 GeV k t = 1.4 GeV, Λ QCD = 0.2 GeV k t = 0.6 GeV, Λ QCD = 0.22 GeV 0 0 5 10 15 20 p t Z (GeV) Non-trivial interplay of many ingredients may lead to puzzles: 1984 UA1 discovery of the top quark with m top = 40 ± 10 GeV. large E jets at the Tevatron, Run I; B-meson production cross-section at the Tevatron, Run I. NuTeV sin 2 θ W. A particular important issue for the LHC is an accurate computation of hard multijet processes (backgrounds to New Physics searches). Physics at the LHC: from Standard Model to new discoveries p. 9/22

The LHC: challenges M eff = p + E miss jets È ALPGEN: exact matrix elements; correct hard emissions built in. PYTHIA: emulates hard emissions by producing large number of softer jets. PYTHIA underestimates the background significantly. Catani-Krauss-Kuhn-Webber procedure to combine shower event generators with exact matrix elements. Physics at the LHC: from Standard Model to new discoveries p. 10/22

The LHC: rediscovering the Standard Model The first priority of the two LHC collaborations is to test and verify their detector performances using basic Standard Model processes: Z l + l, W lν lepton energy scale; tracking efficiency; Z, W parton distribution function, luminosity monitoring; MW. t t b-tagging, jet energy scale W/Z + jets, QCD jets verify theoretical tools. 600 500 Top signal Background Reconstructed Top Mass 400 300 200 100 0 0 50 100 150 200 250 300 350 400 GeV Physics at the LHC: from Standard Model to new discoveries p. 11/22

Hunting the Higgs boson at the LHC Discovery of the Higgs boson is the most important goal of the LHC physics program: test the mechanism of EWSB find the last missing particle of the Standard Model Precision electroweak fits and direct bounds from LEP imply that the Higgs boson mass is m H 100 200 GeV. χ 2 6 4 theory uncertainty α (5) had = 0.02804±0.00065 0.02784±0.00026 m W = 80.3827 0.0579 ln m H 100 0.008 m ln2 H 100 (5) α h 0.517 0.0280 1 mt 2 + 0.543 1 175 2 0.085 αs (m z ) 0.118 1. 0 Excluded Preliminary 10 10 2 10 3 m H [GeV] Physics at the LHC: from Standard Model to new discoveries p. 12/22

Å À Ø Ø Hunting the Higgs boson at the LHC Higgs production processes and decay channels ½ Ï Ï ¼º½ ¼º¼½ Ê Àµ ¼º¼¼½ ¼º¼¼¼½ ½¼¼¼ ¼¼ ¼¼ ¼¼ ¾¼¼ ½ ¼ ½ ¼ ½¼¼ Î The quality of the Higgs signal is determined by the relative magnitude of the signal and the background. Promising discovery channels pp gg H γγ; pp gg H ZZ 4l; pp WH l νe γγ pp gg H W + W l + l ν e ν e. Physics at the LHC: from Standard Model to new discoveries p. 13/22

Hunting the Higgs boson at the LHC For the light Higgs boson, the gg H γγ is the most important channel. However: The background from prompt photon production is overwhelming; Excellent resolution on the photon energy is required; Experimental studies of the background in signal-free regions. Events / 2 GeV 20000 17500 15000 12500 Signal-background, events / 2 GeV 1500 1000 500 0 10000 105 120 135 m γγ (GeV) 105 120 135 m γγ (GeV) Physics at the LHC: from Standard Model to new discoveries p. 14/22

Hunting the Higgs boson at the LHC The significance of the Higgs signal S/ B. Signal significance 10 2 H γ γ tth (H bb) H ZZ (*) 4 l H WW (*) lνlν H ZZ llνν H WW lνjj Total significance For m H = 115 GeV, L = 10 fb 1 : H γγ t th(b b) qqh(ττ) 10 ATLAS 5 σ S 130 15 10 B 4300 45 10 S/ B 2 2.2 2.7 L dt = 30 fb -1 (no K-factors) 1 10 2 10 3 m H (GeV) H γγ electromagnetic calorimetry; t th(b b) efficient b-tagging; qqh(ττ) efficient central jet veto. Physics at the LHC: from Standard Model to new discoveries p. 15/22

Is this really the Higgs boson? The Standard Model Higgs has to couple to matter and gauge fields in a unique way g (H,X) g 2 (H,X) 2 1 0.9 0.8 g 2 (H,Z) g 2 (H,W) g 2 (H,τ) g 2 (H,b) g 2 (H,t) The Hgg coupling counts the number of ultra-heavy quarks: 0.7 0.6 0.5 0.4 0.3 0.2 Γ H without Syst. uncertainty 2 Experiments -1 L dt=2*300 fb -1 WBF: 2*100 fb t, T,.. H QCD corrections 100%; challenge to theorists 0.1 0 110 120 130 140 150 160 170 180 190 m H [GeV] Physics at the LHC: from Standard Model to new discoveries p. 16/22

Searching for BSM physics When we search for New Physics, we do not know what we are loooking for. First, figure out that something is there; then, figure out what this is. Models collider signatures. Many models but relatively few signatures New models new signatures Important New models old signatures Less important Signatures, generic and not: bump hunting (Z, W, extra dimensions, technicolor); high p jets and missing E (SUSY). monojets (extra dimensions); long-lived new particles in the detector (split-susy). Physics at the LHC: from Standard Model to new discoveries p. 17/22

Bump hunting Many BSM models predict the existence of new resonances (new U(1) bosons, extra dimensional theories, technicolor) Events / 20 GeV 10 3 10 2 Dilepton invariant mass spectrum Z χ, Γ=24.1GeV Z ψ, Γ=13.1GeV Z η, Γ=14.4GeV Z LR, Γ=38.6GeV SM -1 L=100fb a) Events/4 GeV 20 18 16 14 12 10 8 Signal SM 6 10 4 1000 1100 1200 1300 1400 1500 1600 1700 1800 M ll [GeV] 2 0 1460 1480 1500 1520 1540 e + e - Pair Mass (GeV) Events/0.2 16 14 Spin-1 12 10 8 qq _ Techni-hadrons V V ρ T V V 4l are hard; Spin of Z vs. RS gravitons can be determined; 6 gg 4 2 0 SM -0.5 0 0.5 cos( θ*) Physics at the LHC: from Standard Model to new discoveries p. 18/22

Jets + E miss : SUSY at the LHC In typical SUSY models, squark and gluino production cross-sections are large, 10 pb. Decays of squarks and gluinos produce jets, leptons and missing energy. Heavy objects lead to larger values of Meff = È p + E miss than in the SM. Mass scale of SUSY is determined from the position of the peak in Meff distribution. Beyond that, determining the masses SUSY particles and establishing their properties is rather challenging. 10-7 10-8 LHC Point 5 m 1/2 (GeV) 1400 1200 3 years, high lumi (300 fb -1 ) A 0 = 0, tanβ = 35, µ > 0 1 year, high lumi (100 fb -1 ) g ~ (3000) h(123) g ~ (2500) dσ/dm eff (mb/400 GeV) 10-9 10-10 10-11 10-12 10-13 0 1000 2000 3000 4000 M eff (GeV) 1000 TH 800 600 400 h (114) mass limit 200 0 0 500 1000 1500 2000 g ~ (500) q ~ (500) q ~ (2000) 1 year, low lumi (10 fb -1 ) 1 month, low lumi (1 fb -1 ) q ~ (1000) q ~ (1500) g ~ (2000) g ~ (1000) q ~ (2500) g ~ (1500) m 0 ( GeV) S. Abdullin Physics at the LHC: from Standard Model to new discoveries p. 19/22

Jets + E miss : large extra dimensions The world may have more than 3 + 1 dimensions: Large extra dimensions, warped extra dimensions, universal extra dimensions, etc. Models and phenomenology vary significantly; ranging from resonance-like excitations to missing energy. Large extra dimensions: SM on the brane, gravity in the bulk. Natural scale for gravity MD 1 Tev; GN R δ M 2 δ D ; δ > 2 3, MD > few 100 GeV (cosmology, astroparticle, Tevatron). Events / 20 GeV 10 6 10 5 10 4 10 3 10 2 δ = 2 M D = 5 TeV s = 14 TeV jw(eν), jw(µν) jw(τν) jz(νν) Signal Basic LHC signature: jet + E miss that originates from (multiple) graviton emission gg G + jet. Backgrounds: Z(ν ν) + jet, W(eν) + jets, etc. Reach: MD < 6 TeV, δ = 2 4. 10 1 0 200 400 600 800 1000 1200 1400 1600 1800 2000 E miss T (GeV) Physics at the LHC: from Standard Model to new discoveries p. 20/22

Long-lived gluinos: split-susy Split-SUSY scenario: all squarks have masses 10 6 TeV; gauginos and the SM Higgs boson is at electroweak scale. New phenomenology long-lived gluinos: lifetimes between 10 12 sec to years. Signatures: Displayed decays; Delayed decays events with beams off; Energy deposition in hadronic calorimeter; Physics at the LHC: from Standard Model to new discoveries p. 21/22

Conclusions The LHC opens up a new energy frontier which might be relevant for most fundamental physics questions of out time; The LHC will discover the Higgs boson within several years; The LHC will likely discover new forms of matter if their masses are within few TeV; The LHC will have a hard time in identifying the model the ILC? The LHC physics is complex and interveined; requires different expertise and support from different components of particle physics community. Physics at the LHC: from Standard Model to new discoveries p. 22/22