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The MESSM

The MESSM. The M inimal E xceptional S upersymmetric S tandard M odel. Richard Howl. University of Southampton. UK BSM 2007. 1 / 12. The MESSM. MESSM = M inimal E xceptional S upersymmetric S tandard M odel. An SUSY Grand Unified Theory based on the.

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The MESSM

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  1. The MESSM The Minimal Exceptional Supersymmetric Standard Model Richard Howl University of Southampton UK BSM 2007

  2. 1 / 12 The MESSM MESSM = Minimal Exceptional Supersymmetric Standard Model An SUSY Grand Unified Theory based on the Like the , MESSM attempts to solve the - problem of the MSSM But without the theoretical difficulties caused by incomplete multiplets that are introduced in the for gauge coupling unification

  3. 2 / 12 A popular solution is to introduce a SM singlet and a superpotential term: (dynamically produced) However, this term creates a global (PQ) symmetry which will produce aGoldstoneboson when gets its VEV One way to avoid this Goldstone boson is to embed the global Inside a localThe would-be Goldstone boson gets ‘eaten’ The bilinear - term is forbidden by this local symmetry The - Problem MSSM superpotential contains which gives mass to the Higgsinos Important for determining the Higgs scalar potential and the pattern of Electro-weak Symmetry Breaking (EWSB) From phenomenology we require SUSY breaking (or EW) scale is a free parameter, term is SUSY invariant, can be present before why SUSY breaking (not e.g. ) ? SUSY is broken

  4. 3 / 12 The - Problem in SUSY GUTs Gauge coupling unification for MSSM suggests can embed it within some Supersymmetric Grand Unified Theory If assume GUT exists and wish to solve the - problem with a and , then both of these must be derived from the Grand Unified Theory VEV could then be determined from a radiative mechanism from GUT However: SUSY GUTs colour triplet particles: , when we embed into complete GUT multiplets Can cause rapidproton decay and can destroy gauge coupling unification Most popular solution is to give large (GUT scale) mass to via a doublet-triplet splitting mechanism don’t participate in low energy theory and proton decay suppressed

  5. 4 / 12 The - Problem in SUSY GUTs Problem: Since and come from the same representations: To generate the term, we generally also get a term With a large effective mass term, could generally acquire a large effective VEV from (one-loop tadpole diagrams) destroying EWSB Whereas if have small masses (EW scale) then they can affect the RGEs to help drive the soft square mass of large and negative Also, light could be used to cancel any anomalies for the Suggests should try to keep ‘light’ (to solve – problem)

  6. 5 / 12 1 1 1 2 2 2 Must only suppress the terms that induce proton decay and not However, we cannot not have all ‘small’ since then would the terms that allow the triplets to decay become stable particles. e.g. apply a discrete symmetry on the leptons or the leptons and triplets From standard Big Bang cosmological arguments we should be able to observe strong interacting ‘heavy’ stable particles in hadrons today Then or are allowed but the other is forbidden Strong limits put on such stable particles with mass between proton decay sufficiently suppressed and are no longer stable 1GeV to 10TeV Another possibility could be to apply a family symmetry and / or generate Must try to suppress the terms that induce proton decay but not or viahigher dimensional operators more work needed the terms that allow the triplets to decay Suppressing Proton Decay generally interact with quarks and leptons in GUTs via these terms: Induce proton decay via d = 6 operators suppressed by Therefore if are light we must suppress proton decay by making Yukawaconstants sufficiently small

  7. 6 / 12 Repairing Guage Coupling Unification Proton decay now suppressed butkeeping light spoils the unification of the MSSM: (2 – loop)

  8. 6 / 12 Repairing Guage Coupling Unification Proton decay now suppressed butkeeping light spoils the unification of the MSSM: (2 – loop) The Black line indicates mass of The green lines show their effect on the RGEs

  9. 6 / 12 Repairing Guage Coupling Unification Proton decay now suppressed butkeeping light spoils the unification of the MSSM: (2 – loop) (No Unification) The Black line indicates mass of The green lines show their effect on the RGEs

  10. 6 / 12 A possible solution is to add two additional EWdoublets to light spectrum have added two complete multiplets ( ) to the MSSM Repairing Guage Coupling Unification Proton decay now suppressed butkeeping light spoils the unification of the MSSM: (2 – loop)

  11. 6 / 12 However these new particles could introduce theoretical problems: A possible solution is to add two additional EWdoublets to light spectrum How to keep the two extra doublets light but rest of GUT multiplet heavy. have added two complete multiplets ( ) to the MSSM Essentially a D-T (mass) splitting problem Repairing Guage Coupling Unification Proton decay now suppressed butkeeping light spoils the unification of the MSSM: (2 – loop) (higher unification coupling constant than for MSSM.) e.g.

  12. 7 / 12 An example of a SUSY GUT that requires two additional EW doublets for gauge coupling unification is the is essentially an SUSY GUT that breaks to and places the quarks, leptons,, into 3 generations of a from and are both used to solve the - problem of the MSSM All 3 generationsof are ‘light’ to help solve the - problem and to cancel gauge anomalies contains like MSSM + complete reps. ( ) + spoil unification Unification in the ESSM

  13. 7 / 12 An example of a SUSY GUT that requires two additional EW doublets for gauge coupling unification is the is essentially an SUSY GUT that breaks to and places the quarks, leptons,, into 3 generations of a from and are both used to solve the - problem of the MSSM All 3 generationsof are ‘light’ to help solve the - problem and to cancel gauge anomalies contains like MSSM + complete reps. ( ) + spoil unification Unification in the ESSM e.g. In matter and Higgs are put into 3 generations of a All 3 generations of are ‘light’

  14. 7 / 12 All 3 generations of are ‘light’ All 3 generations of are ‘light’ + two extra doublets like MSSM + complete reps. ( ) + like MSSM + complete reps. ( ) Unification in the ESSM e.g. In matter and Higgs are put into 3 generations of a spoil unification

  15. 7 / 12 All 3 generations of are ‘light’ + two extra doublets like MSSM + complete reps. ( ) Problems: No explanation for why are light but rest of their complete representations are at GUT scale a D-T splitting problem The extra doublets are given mass via a ‘ - term’ : Why does SUSY breaking scale (and not e.g. )? Introduced another - problem to the theory ! Unification in the ESSM e.g. In matter and Higgs are put into 3 generations of a

  16. 8 / 12 Unification with Intermediate Symmetries A way of avoiding these new doublet particles could be to use an intermediate symmetry to ‘repair’ the unification instead non-simple groupGrand Unified Group gauge couplings no longer need to unify but instead turn into gauge couplings (at the symmetry breaking scale) which do unify e.g. in and we could use a left-right symmetric Pati-Salam: At the P-S symmetry breaking scale the SM gauge couplings must satisfy: (When GUT normalized and with ) P-S symmetry breaking scale determined from running gauge couplings with energy until they satisfy the above equation.

  17. 9 / 12 Unification with Intermediate Symmetries e.g. with quarks, leptons, in a fundamental All 3 generations of ‘light’.

  18. 9 / 12 e.g. with quarks, leptons, in a fundamental All 3 generations of ‘light’. Can now obtain unification if: Unification occurs at Planck scale using standard RGEs. Effect of quantum gravity on RGEs is unknown could spoil unification However, unification at Planck scale is suggestive of a unification of the gauge fields with gravity. Use Higgs multiplets from to break P-S symmetry. assumed quantum gravity does not spoil this unification but instead Assumed have mass of order of the P-S breaking scale. could unify gravity with the gauge fields. Unification with Intermediate Symmetries

  19. 10 / 12 The MESSM If assume Planck scale unification then can use an intermediate symmetry rather than two EW doublets for gauge coupling unification. avoiding the theoretical difficulties they introduce. The MESSM is based on the but uses a Pati-Salam symmetry for gauge coupling unification instead of the EW doublets no need for a D-T splitting mechanism or the extra term To break P-S to SM we use Higgs bosons from with VEVs in direction : from and are used to solve - problem of MSSM are singlets of the SM Can generate conventional see-saw mechanisms.

  20. 11 / 12 The MESSM Pati-Salam symmetry broken at symmetry assumed to be broken at the Planck mass scale

  21. 12 / 12 Summary The MESSM attempts to solve the - problem of the MSSM using a SM singlet particle and a local group from an GUT To help solve the - problem and to cancel anomalies, all 3 generations of light. (including the colour triplets) To ‘repair’ the gauge coupling unification an intermediate Pati-Salam symmetry is used. The P-S symmetry is broken at the GUT scale The symmetry is assumed to be broken at the Planck mass scale. The Higgs bosons used to break P-S come from which can havethe same (GUT scale) mass No multiplet (mass) splitting.

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