1 Status of the SUSY Les Houches Accord 2 project RPV, CPV, FLV, NMSSM & more S. Heinemeyer (P. Skands) February 2006.

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Presentation transcript:

1 Status of the SUSY Les Houches Accord 2 project RPV, CPV, FLV, NMSSM & more S. Heinemeyer (P. Skands) February 2006

2 SUSY Les Houches Accord v1 Writeup in JHEP 0407:036,2004 Les Houches  Lots of people, lots of discussions, lots of head-aches SUSY is old. Different models + different people + different tools  different conventions Accord  one convention, less head-ache

3 SUSY Les Houches Accord v1 + F77 I/O Library by T. Hahn (now also NMSSM) SUSY MODEL MSSM SUGRA GMSB AMSB NMSSM RPV CPV FLV … CPSUPERH FEYNHIGGS ISASUSY NMHDECAY SOFTSUSY SPHENO SUSPECT … SPECTRUM CALCULATOR CALC/COMPHEP AF’S SLEPTONS GRACE HERWIG (++) ISAJET PROSPINO PYTHIA SHERPA SMADGRAPH SUSYGEN WHIZARD … MC EVENT GEN / XS CALCULATOR MICRΩS DARKSUSY NEUTDRIVER PLATON (?) CDM PACKAGE DECAY PACKAGE FEYNHIGGS HDECAY NMHDECAY SDECAY SPHENO spectrum spc+dec spc input spectrum       FITTINO, SFITTER FITTERS 

4 The SLHA1 Conventions 1.Experimental boundary conditions “SM” gauge couplings and Yukawas (measured)  “MSSM” couplings and Yukawas (not the same, since different field content  different quantum corrections) 2.Superpotential (at scale Q (normally M GUT ) in DRbar) 3.SUSY Breaking Terms (at scale Q in DRbar) A ¹ m A M 1 2 m o

5 How to Generalise? MSSM 2.Superpotential (at scale Q (normally M GUT ) in DRbar) RPV CPV FLV 3.SUSY Breaking Terms (at scale Q in DRbar)

6 How to Generalise? Model Definition Additions to global switches in block MODSEL : 3)Choice of particle content 0: MSSM (default) 1: NMSSM 4)R-parity violation 0: R-parity conserved (default) 1: R-parity violated 5)CP violation 0: CP conserved (default) 1: CP violated but only by CKM phase 2: CP violated, general phases allowed 6)Flavour violation 0: No (SUSY) flavour violation (default) 1: Flavour violated

7 How to Generalise? MSSM 4.Work out physical Spectrum Pole masses, Imaginary sneutrinos … (codes , , ) EW scale Lagrangian parameters Need to specify all Lagrangian couplings (see below …) + effective vertices? (nothing yet  SLHA3 ???) EW scale mixings CPV+RPV+FLV  basically, every state with same colour, spin, and EM charge can mix! For the time being, we restrict to either RPV or CPV.

8 INPUT –New input blocks for all RPV superpotential parameters, soft-breaking parameters, and sneutrino vevs (all with prefix “RV” and suffix “IN”) LAGRANGIAN PARAMETERS (all DRbar at scale Q) : –New output blocks for all RPV parameters (prefix “RV” but no suffix) POLE MASSES –“PDG” codes for imaginary sneutrinos: , , EW SCALE MIXING: –RVNMIX: 7x7 neutralino/neutrino mixing –RVUMIX, RVVMIX: 5x5 chargino/lepton mixing  example … –RVHMIX: 5x5 CP-even Higgs/sneutrino mixing –RVAMIX: 5x5 CP-odd Higgs/sneutrino mixing –RVLMIX: 4x4 Charged Higgs/slepton mixing How to Generalise? RPV incl. Goldstones (?)

9 Mixing Example: Charged colour-singlet fermions How to Generalise? RPV Flavour basis e + = e + flavour eigenstate mu + = mu + -”- tau + = tau + -”- -i ~w + = charged wino ~h2 + = charged higgsino (up-type) Mass basis (PDG numbers), strictly mass-ordered : -11 (e + )= lightest state (regardless of composition!) -13 (mu + )= 2 nd lightest -15 (tau + )= 3 rd lightest (chi1 + )= … (chi2 + )= heaviest charged colour-singlet fermion

10 How to Generalise? FLV Flavour Violation at Les Houches (Chamonix) : Fondue au sucre! Already some experience with FLV!

11 How to Generalise? FLV SUPER-CKM BASIS: –defined as basis in which quark Yukawas, in DRbar, are diagonal –NB: lepton mixing not treated yet (though see RPV). INPUT –VCKMIN: V CKM in PDG parametrisation (SM MSbar at M Z ). –SMINPUTS: Include m u,d,s (2GeV) MSbar and m c (m c ) MSbar –NB: no explicit proposal yet for input of non-diagonal soft SUSY-breaking trilinear and bilinear terms, e.g. MSQIN, MSUIN, MSDIN? LAGRANGIAN PARAMETERS (all DRbar at scale Q) : –Yukawas: Super-CKM basis  always diagonal (but same blocks as SLHA1) –VCKM and bilinear SUSY-breaking MSQ, MSU, MSD matrices EW SCALE MIXING: –USQMIX: 6x6 up-squark mixing in super-CKM basis –DSQMIX: 6x6 down-squark mixing in super-CKM basis

12 How to Generalise? CPV SIMPLEST WAY –Add prefix “IM” to already existing SLHA1 blocks –E.g. in input: IMEXTPAR; in output: IMNMIX etc … –Not completely general, but useful starting point MORE GENERAL –Add prefix “IM” to new SLHA2 blocks (supersede SLHA1 if present) EW SCALE MIXING: –CVHMIX: 4x4 neutral Higgs (CP-even & CP-odd) mixing –IMCVHMIX: imaginary parts –Charged Higgs mixing (2x2) not yet agreed upon

13 How to Generalise? NMSSM Cf. NMHDecay, Ellwanger, Gunion, Hugonie 2.Superpotential (at scale Q (normally M GUT ) in DRbar) (usually with μ MSSM =0) NMSSM 3.SUSY Breaking Terms (at scale Q in DRbar) EXTPAR: 61)lambda 62)kappa 63)A_lambda 64)A_kappa 65)mu_eff=lambda 4.Physical Spectrum 3 H 0 (PDG: 25,35,45), 2 A 0 (PDG: 36, 46), 5χ 0 (PDG: ) Mixing: NMHMIX NMAMIX NMNMIX See also MicrOMEGAs & CalcHEP + Interface to PYTHIA

14 Cross Sections & Theory Errors NB: Not included in current LH status report Theory Errors –Introduce (unphysical) input variables corresponding to variations within theoretical uncertainty -> range of spectra. (Similar in spririt to error PDF's) –Calculation of observables from spectrum  +/- errors on computed variables Cross Sections used by fit programs – Templated in SPheno. Collecting experiences now. Fittino, Sfitter These (and more?) to be included in journal writeup

15 Outlook ‘Conceptual Design Report’ for SLHA2 prepared for Les Houches BSM Proceedings, to appear on archives soon. Concerns core SLHA2 conventions. More extensive writeup to follow in To discuss: –MC4BSM, Fermilab, Mar 20-21, 2006 (non-SUSY BSM) –Flavour in the Era of the LHC, CERN, May 15-17, 2006 (flavour) –Tools 2006, Annecy, Jun 26-28, 2006 –MC4LHC, CERN, Jul 17-26, 2006 See also Les Houches BSM tools repository:

16 Conclusions Tough conditions call for good tools! We will be ready for NMSSM, CPV, RPV, FLV, … Then all we need is a signal …

17 Work 1 W MSSM = ² a b £ ( Y E ) ij H a 1 L b i ¹ E j + ( Y D ) ij H a 1 Q b i ¹ D j + ( Y U ) ij H b 2 Q a i ¹ U j ¡ ¹ H a 1 H b 2 ¤ V 3 = ² a b X ij h ( T E ) ij H a 1 ~ L b i L ~ e ¤ j R + ( T D ) ij H a 1 ~ Q b i L ~ d ¤ j R + ( T U ) ij H b 2 ~ Q a i L ~ u ¤ j R i + h : c :; L G = 1 2 ³ M 1 ~ b ~ b + M 2 ~ w A ~ w A + M 3 ~ g X ~ g X ´ + h : c ::

18 Work 2 L G = 1 2 ³ M 1 ~ b ~ b + M 2 ~ w A ~ w A + M 3 ~ g X ~ g X ´ + h : c :: V 2 = m 2 H 1 H ¤ 1 a H a 1 + m 2 H 2 H ¤ 2 a H a 2 + ~ Q ¤ i L a ( m 2 ~ Q ) ij ~ Q a j L + ~ L ¤ i L a ( m 2 ~ L ) ij ~ L a j L + ~ u i R ( m 2 ~ u ) ij ~ u ¤ j R + ~ d i R ( m 2 ~ d ) ij ~ d ¤ j R + ~ e i R ( m 2 ~ e ) ij ~ e ¤ j R ¡ ² a b ( m 2 3 H a 1 H b 2 + D i L a i H b 2 + h : c : ) : m LiHLiH L a i H b 1 +

19 Work 3 W = W MSSM + ¸ ² a b SH a 1 H b 2 + · 3 S 3 V 3 = V 3 ; MSSM + ( ² a b ¸ A ¸ SH a 1 H b 2 + h : c : ) + · 3 A · S 3 ; V 2 = V 2 ; MSSM + m 2 S S 2