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SUPERSYMMETRIC EXTENSION OF THE STANDARD MODEL

SUPERSYMMETRIC EXTENSION OF THE STANDARD MODEL. Outline. DMITRI KAZAKOV JINR / ITEP. What is SUSY Motivation of SUSY The MSSM SUSY Searches SUSY in Astrophysics. What is SUSY. Supersymmetry is a boson-fermion symmetry that is aimed to unify all forces in Nature including

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SUPERSYMMETRIC EXTENSION OF THE STANDARD MODEL

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  1. SUPERSYMMETRIC EXTENSION OF THE STANDARD MODEL Outline DMITRI KAZAKOV JINR / ITEP • What is SUSY • Motivation of SUSY • The MSSM • SUSY Searches • SUSY in Astrophysics

  2. What is SUSY • Supersymmetry is a boson-fermion symmetry • that is aimed to unify all forces in Nature including • gravity within a singe framework • Modern views on supersymmetry in particle physics • are based on string paradigm, though low energy • manifestations of SUSY can be found (?) at modern • colliders and in non-accelerator experiments • The concepts of Quantum Field Theory allow SUSY • without any restrictions • There is no direct confirmation of SUSY but this does • not stop theorists due to extreme beauty of SUSY models

  3. Supersymmetry Local translation = general relativity !

  4. The Standard Model • Fits the experimental data very well • Has too many free parameters and unexplained features • The Higgs boson is still missing

  5. Comparison with Experiment Global Fit to Data Higgs Mass Constraint Though the values of sin w extracted from different experiments are in good agreement, two most precise measurements from hadron and lepton asymmetries disagree by 3 Remarkable agreement of ALL the data with the SM predictions - precision tests of radiative corrections and the SM

  6. The SM and Beyond The problems of the SM: • Inconsistency at high energies due to Landau pole • Large number of free parameters • Formal unification of strong and electroweak interactions • Still unclear mechanism of EW symmetry breaking • CP-violation is not understood • Flavour mixing and the number of generations is arbitrary • The origin of the mass spectrum in unclear The way beyond the SM: • The SAME fields with NEW • interactions GUT, SUSY, String • NEW fields with NEW • interactions Compositeness, Technicolour, preons

  7. We like elegant solutions

  8. Motivation of SUSY in Particle Physics • Unification with Gravity • Unification with Gravity • Unification of gauge couplings • Solution of the hierarchy problem • Dark matter in the Universe • Superstrings Unification of matter (fermions) with forces (bosons) naturally arises from an attempt to unify gravity with the other interactions

  9. Motivation of SUSY in Particle Physics • Unification of gauge couplings Running of the strong coupling

  10. Motivation of SUSY RG Equations Input Output SUSY yields unification!

  11. Motivation of SUSY • Solution of the Hierarchy Problem Cancellation of quadratic terms Destruction of the hierarchy by Radiative corrections

  12. Motivation of SUSY • Dark Matter in the Universe The flat rotation curves of spiral galaxies provide the most direct evidence for the existence of large amount of the dark matter. Spiral galaxies consist of a central bulge and a very thin disc, and surrounded by an approximately spherical halo of dark matter SUSY provides a candidate for the Dark matter – a stable neutral particle

  13. Particle Content of the MSSM sleptons leptons squarks quarks Higgses { higgsinos{

  14. SUSY Shadow World One half is observed! One half is NOT observed!

  15. SUSY Lagrangians Superfields Components Potential

  16. The MSSM Lagrangian The Yukawa Superpotential superfields Yukawa couplings Higgs mixing term R-parity B-Bartion Number L-Lepton Number S-Spin The Usual Particle : R= + 1 SUSY Particle : R= - 1

  17. R-parity Conservation The consequences: • The superpartners are created in pairs • The lightest superparticle is stable Physical output: • The lightest superparticle (LSP) should be neutral - the best candidate is neutralino (photino or higgsino) • It can survive from the Big Bang and form the Dark matter in the Universe

  18. Interactions in the MSSM Creation of superpartners Interaction Vertices Decay of superpartners

  19. Soft SUSY Breaking Hidden Sector Scenario: SUGRA The Universal Soft Parameters: and Versus and in the SM

  20. Mass Spectrum Neutralino Chargino Squarks & Sleptons

  21. SUSY Higgs Bosons SM MSSM

  22. The Higgs Potential Minimization Solution At the GUT scale No SSB in SUSY theory !

  23. Radiative EW Symmetry Breaking Due to RG controlled running of the mass terms from the Higgs potential they may change sign and trigger the appearance of non-trivial minimum leading to spontaneous breaking of EW symmetry - this is called Radiative EWSB

  24. Constrained MSSM Requirements: • Unification of the gauge couplings • Radiative EW Symmetry Breaking • Heavy quark and lepton masses • Rare decays (b -> sγ) • Anomalous magnetic moment of muon • LSP is neutral • Amount of the Dark Matter • Experimental limits from direct search Allowed region in the parameter space of the MSSM Parameter space:

  25. SUSY Fits Minimize

  26. Low and High tanβ Solutions • Requirements: • EWSB • bτ unification Low tanβ solution High tanβ solution • bτ unification is the • consequence of GUT • Non working for the • light generations

  27. Allowed Regions in Parameter Space All the requirements are fulfilled simultaneously ! • μ is defined • from the EWSB * - is the best fit value

  28. Masses of Superpartners

  29. Mass Spectrum in CMSSM SUSY Masses in GeV Fitted SUSY Parameters

  30. SUSY Searches m+  100 GeV m0  40 GeV mg  300 GeV ~ ~ mq  300 GeV ml 100 GeV ~ ~

  31. SUSY Production at Hadron Colliders Annihilation channel Gluon fusion, qq scattering and qg scattering channels No new data so far due to insufficient luminocity at the Tevatron

  32. The Higgs Mass Limit • Indirect limit from radiative corrections • Direct limit from Higgs non-observation at LEP II (CERN) 113 < mH < 200 GeV At 95 % C.L.

  33. The Higgs Mass Limit (Theory) • The SM Higgs mH  134 GeV SUSY Higgs mH 130 GeV

  34. Higgs Searches mH  113.4 GeV at 95 % C.L. 114 -115 GeV Event

  35. Allowed Regions Renewed • from the • Higgs limit at LEP • μ>0 from

  36. Cosmological Constraints New precise cosmological data • Supernova Ia explosion • CMBR thermal fluctuations (recent news from WMAP ) Hot DM (not favoured by galaxy formation) Dark Matter in the Universe: Cold DM (rotation curves of Galaxies)

  37. SUSY Fits to Dark Matter Results in severe constraints on parameter space

  38. SUSY Search in Space Cosmic ray spectrum at high energies Excess

  39. Positrons from Neutralinos of the Dark Matter

  40. AMS – Antimatter Search in Space at ISS Will be able to check SUSY Dark matter predictions

  41. Superparticles Discovery of the new world of SUSY Back to 60’s New discoveries every year

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