Minutes of Heavy Higgs  BSM Group (26 June 2013)
Link to the agenda
Higgs (or physical) basis and implementation in Sushi+2HDMC
The Higgs basis is fully worked out for the CP conserving case with h126 as light 0+ state and it is under implementation in Sushi+2HDMC
Comments:
 in the Higgs basis, asking for Z_i<1 should be enough to enforce unitarity/perturbativity
 next generalization: CP not conserving case, h126 the high mass 0+ state
 implementation in 2HDMC will be transparent: can be used as the other basis
 CMS and ATLAS can play with 2HDMC+Sushi even now (Higgs basis still under development but other basis available)
Scan of benchmark points (Summary of discussion of 18 June)
 If all masses forced to be the same then only s(ba) very near 1 is possible
 allowing masses to float (splitting between charged Higgs mass and heavy 0+ mass) then also small values of s(ba) are allowed (with low tab no finetuning is needed)
 observation of h126 suggest large s(ba) but the uncertainties on signal strenght are large and experiments want to keep an openmind approach:
 identify which region of parameter space makes sense theoretically (unitarity constraints etc...)
 inject the knowledge of h126 observation considering the mass only
 inject the knowledge of h126 observation considering the mass and the signal strenght (still large uncertainty at 3 sigma level)
 the identified benchmarks should then be related to the experimental parameters (eg, width) and BR for decays (eg H>hh)
 We will have to consider not only xsec*BR but also how the kinematic will change. Also we need MC for specific decays eg H>hh
H/A>ttbar
 phenomenological work ongoing to describe properly interference effects with background
 in 0 case total width is ~equal to ttbar width
 also when ttbar width smaller than total width (eg 0+) still large interference effects
 interference will also have an effect on total normalization
 first experimental study on these effects started in CMS > suggestion to move to NLO tools
Minutes of Heavy Higgs  BSM Group (15th May 2013)
In this meeting we continued to discuss 2HDM benchmarks. One of the main problems we are facing is that already a large parameter space is excluded by constraints from unitarity and perturbativity, as Nikos and Oscar showed in their talks. Assuming some Higgs mass degeneracy and fine tuning m12 was not helping much in this regard. In the discussion, it was also agreed on that the current observation of the experiments at 125 GeV should be fully taken into account. This will lead to scenarios with sin(β – α) very close to 1.
Howard was presenting a strategy for choosing 2HDM benchmark points. For this approach, the model is written in the Higgs basis, where unitarity constraints are explicit. To choose benchmark points, the observation at 125 GeV is identified with h1. Parameters s12 and s13 are chosen such that h1VV couplings are SMlike. Now one can choose the remaining parameters such that they satisfy unitarity. Finally, we need to convert back to the masseigenstate basis used by SusHi and 2HDMC.
In the searches Higgs width effects should be controlled. As Oscar showed, they can be calculated with the 2HDMC. For some parameter choices the H width can be enhanced in the low mass range compared to SM case. The H width can also be very large when approaching the nonperturbative regime.
Oscar and Robert also work on an “official” interface between SusHi and 2HDMC. Here the cross section calculation can be set up in SusHi which is linked to 2HDMC for calculation of physical masses and mixings, theoretical constraints, and branching ratios. The public version of this is already in preparation, and will soon be available for interested LHCXSWG members for early testing.
Gunar discussed changes in the Higgs pT wrt tan β. At high values of tan β the bottom contributions become dominant. This modifies the average quark mass in the loop of the gluonfusion production, as well as the turnon of the bbH production which comes with a recoil. Both have an effect on the Higgs pT, which becomes smaller at higher Higgs masses. These effects can be checked with SusHi, which calculates gluonfusion production at O(alpha_s^3) and bbH production up to O(alpha_s). SusHi can be used to apply a reweighting of the SM samples for different tan β values.
Some further remarks:
VH@NNLO: Robert and collaborators are working on a consistent way to scale the calculation also at the QCD NNLO. The gluonfusion contribution is proportional to the ttH coupling and needs a separate scaling.
VBF@NNLO: Fabio/Marco explained that for VBF the situation is slightly different. The quarkloop terms turn out to be much smaller than for VH, and can be safely neglected.
There was no progress on the missing higherorder EW corrections in the 2HDM. As we are so far setting only exclusions limits we might neglect them in the first approximation, however some rough idea of associated uncertainties would be great to have.
ToDo list:
 Finalise benchmark proposals. For this we need to convert from the Higgs to the masseigenstate basis. Nikos agreed to follow up on this, with the help of Howard and Oscar.
 Two further interesting benchmark scenarios should be considered as well.
a. The observed Higgs boson is the heavier one (H)
b. The observed Higgs signal is due to degenerate states
 Proposal for the treatment of the missing higherorder EW corrections
Probably the most useful would be to meet again soon, once Howard, Nikos and Oscar have a first concrete benchmark proposal.
Minutes of Heavy Higgs  BSM Group (30st April 2013)
Link to the agenda
Introduction
Brief recap of scope of the group and recipes ready for the SM case and work ongoing on SM VBF and BSM (EWsinglet and 2HDM).
Comments:
 Once we agree on common recipe we should have a repository with actual numbers stored to be shared between ATLAS and CMS
Work already ongoing (see here):
 WW results from ATLAs and CMS under comparison,
 ZZ>2l2n only from CMS for now,
 ZZ>4l provided by Giampiero (will be crosschecked with gg2VV)
EWsinglet
Bounds on parameters space from theoretical study and some ideas on EWK corrections
Comments:
 Is sinAlpha enough to describe the model? Why also tgBeta mentioned?
tgBeta enters in H>hh couplings and H selfcouplings, all second order effects
 Limits on signal strength of h126 from experiments should be considered taking twice the error (roughly equivalent to 95% CL). Most of the limit plots for that case are already shown in the paper (just Gammak plane missing but can be easily done). At low mass this doesn't matter (limits from perturbativity more important than limit due to measured h signal strength)
 H>ttbar may be modified (at the order of 10%) by loop with h [tbc, just raw estimate]
 How perturbative unitarity has been imposed? Just asking VV scattering to not explode (there are more complicated methods). Actually the fastest divergence comes from H>HH
 Some symmetries imposed to write the potential, how much general and how removing them would change the limit shown here? What if operators which violates FCNC at small level are included? z3 symmetry studied by other authors [JCAP 1301 (2013) 022].
 Question: is the naive estimate Gamma_tot/m_H as an error you make in the narrow width approximation correct (ie if you do the "correct" calculation w the complex pole scheme, is the error much larger/ smaller than the estimated one wrt the nwa ?). (Answer offline: yes the CPS results can be outside the narrow width uncertainty given by Gamma/mH, see for instance slide 5 of first talk)
NNLO gg>WW with softcollinear approximation
gg>WW S+B+I computed at NNLO with softcollinear approximation
Comments:
 main approximation comes from integrating out top and bottom mass in the loop (in cbar terms). In the Higgs case cbar~11 with mtop to infinity, cbar~11.47  6.57 for mh 480720 with correct mtop. Uncertainties computed by considering +/5*cbar, how uncertainties change with different factors in front of cbar?
 +/ cbar > ~1% uncertainty
 +/ 5 * cbar > ~8% uncertainty
 +/ 10 * cbar > ~1520% uncertainty
 these are just the uncertainties related with cbar (eg, total uncertainty in the first case is 5%)
 is this computation reliable for exclusive analysis in different jet bins? No, approximation does not describe well the kinematic of the additional partons
 similar calculation for qq>WW ongoing
Minutes of Heavy Higgs  BSM Group (22nd March 2013)
Link to the agenda
The main topic of this meeting was to discuss how ATLAS and CMS can explore the best way searches to the generic two Higgs doublet models (2HDM). As the parameter space is large, some simplifications/benchmarks are desirable.
ATLAS presented recently an analysis where a direct search for H is done, while all the other Higgs masses are assumed to be large. The free parameters remain: mH, tan β, α. Exclusion limits were presented on the mH – cos α plane for given tan β assuming type I or type II 2HDM with the condition that the lightest CPeven Higgs boson is identified with the boson at ~125 GeV. For this analysis, the SM Higgs MCs were rescaled with 2HDM couplings (see below for the description of the tools). In this approach one needs to be careful how the SM kinematics gets modified, especially from the bbH contribution. This is more of an issue at high tan β, the ATLAS analysis applied btag veto to minimise this problem. In general, a more quantitative assessment of possible biases could be done with an MSSM bbH MC sample. Top and bottom loop contributions can affect the HpT as well, though this should be a smaller effect, it would be nice to estimate this in the future. Currently, the H width is taken in the narrow width approximation. Since the h@125 GeV couplings to the W/Z are SMlike, the H width should be small, however it can be broadened above 250 GeV by H→hh (needs to be quantified).
Further constraints on the 2HDM parameter space could be set by taking into account the diphoton decay rate of the observed boson at ~125 GeV.
The main available tools for a search of H in the 2HDM scenario are
SusHi and 2HDMC.
BR calculation
2HDMC [CPC 181 (2010) 189] is a generalpurpose calculator for the twoHiggs doublet model and can be used to calculate all 2HDM BRs and width for any parameter at tree
level for the CPconserving scenario. Offshell effects (e.g. h(125)→ZZ→4l, HÂ±→tb) are not yet fully included in the program, however this is being implemented.
Cross section calculation
SusHi [CPC 184 (2013) 1605] is a program for the calculation of Higgs production in gluon fusion and bottomquark annihilation in the MSSM (and SM). If the squark and gluino couplings are switched off, SusHi can be used to calculate general 2HDM cross sections. The program provides exact NLO QCD corrections and NNLO QCD corrections in the heavy top quark limit which are valid for mH < 2 mt. EW corrections are not applicable in the 2HDM scenario and have to be turned off.
The VBF and VH productions in the 2HDM can be estimated with the
VBF@NNLO and
VH@NNLO programs running at the NLO level and then rescale the cross section using the 2HDMC program.
Full higherorder EW corrections are not available in the 2HDM for any of these production modes. For now, the recommendation is to use only an uncertainty for the missing EW corrections. For the gluonfusion production this could be the EW contribution from the lightquarks only which can be calculated with SusHi. For the other production modes the uncertainty can be taken as the magnitude of the SM EW corrections (until a better recommendation is found).
Benchmark choices
Further suggestions of 2HDM benchmark choices: take mh~125
GeV as an input and scan over values of cos (αβ) vs tan β for benchmark choices of λ, λA and λF (linear
combinations of the Higgs selfcouplings). While cos (αβ) should range from 0 to 0.5 (corresponding to a very rough SMlike h), tan β could be taken as 0.5 < tan β < 50. An alternative would be a 3 parameter scan over cos (αβ), tan β and mH and choose benchmark values for λA and λF. Different parameterisations can be mapped to each other with the 2HDMC code.
There was a short discussion on the null hypothesis for the experimental searches. The overall agreement was that for the moment this could be the SM, while the 2HDM scenario is the test hypothesis.
ToDo items for the nearer future
 Extend consideration to type III/IV benchmark models and charged Higgs searches, as well as to the scenario where the boson at 125 GeV is the heavier Higgs H
 Provide cross section / BR tables linked from the LHC HXSWG (Nikos Rompotis started to work on this already)
 Could ask the authors of VBF@NNLO and VH@NNLO to include the 2HDM couplings in a more formal way
 Discuss further the best way how to implement or access the uncertainties due to the missing higherorder EW corrections
 Quantify width effects at higher masses due to H→hh decays
 Quantify kinematic biases compared to the SM expectation in different regions of the parameter space
 Consider the contributions of additional new degrees of freedom (scalars, fermions, vectors) to the H production
Minutes of Heavy Higgs  BSM Group (8th March 2013)
Link to the agenda
Introduction: status and plans of ATLAS/CMS for Heavy Higgs and EWsinglet
Comments:
 SM exclusion up to 1TeV with CPS from ATLAS shown in Moriond. 2HDM analysis ongoing in ATLAS (what about CMS?)
Problem of communication between this group and the experiments
(2HDM ATLAS work should be presented at the next group meeting)
 EW singlet: is it really in the plan of ATLAS? Yes, even if right now there is more interest on 2HDM
 2HDM should be more comprehensive but also much more difficult to workout theoretically (especially at high mass)
 for 2HDM at low mass is SUSHI enough as XS and BR calculator? (Specific for MSSM, needs to be investigated for general 2HDM case)
 need to have a dedicated 2HDM meeting
 At high mass to have in BSM the same precision as SM (NLO) a lot of work needs to be done
 EW singlet is the first step. It can be done by Fall if proper manpower, proper organization and interest from the experiments
 2HDM it is more difficult and it may require more time: at NLO the scaling is not anymore uniform but you have different scaling for each diagram
CMS WW>lnjj: proposal for a LO EWsinglet interpretation at high mass
Comments:
 Why you rescale the SM signal width instead of just using LO BSM gg2VV or MCFM shape?
 the only processed MC we have is Powheg so we need to reweight that
 for signal lineshape we would like to keep the CPS which is much better than running BW approach
 There are 3 interference terms to consider S_h+S_H+B^2 = S_h^2 + S_H^2 + B^2 + I_hH + I_hB + I_HB
 I_hH expected small if the 2 resonance have small width and far away
 I_HB is exaclty what is addressed by the reweigthing schema using MCFM or gg2VV
 I_hb should be checked: how much the gg>VV background at high mass is affected by the presence of low mass h ? (Typical problem in VBF case, expected small in ggH)
Test it by comparing B only production and S_h+B production in MCFM and gg2VV
 Main caveat: we reweight QCD NLO MC with interference correction at LO. (QCD NLO effects on pT expected to be the same in SM and EWsinglet case)
CMS ZZ>llnn: proposal for a LO EWsinglet interpretation at high mass
Comments:
 Same recipe as lnjj in previous talk: in particular, full BSM line shape from LO MC is in reasonable agreement with SM LO lineshape rescaled
 The SM uncertainties obtained by applying different kfactors to interference term cannot be applied here > let's start with 100% uncertainty on the interference correction
 2D plot of upper limit can be produced in 3 ways
 C' vs BRnew
 C' vs width (slightly better, more easy to reinterpret in other models)
 BRnew vs width and xsec exclusion on the z axis:
 difficult to interpret you cannot know where the EWsinglet is really ruled out (ie UL<1)
 misleading because far away from UL=1 (ie far away from xsec= EWsinglet xsec) the reweigthing schema do not work so we are not really excluding any welldefined xsec
 Formulas provided for EWsinglet to rescale couplings and width is valid only in the ZWA approximation. Implementing instead the model in gg2VV and MCFM should includes all the off shell propagator effects (no way to include those in a simple formula)
General discussion about plans and YR3
Lines of work:
 High mass SM case:
 ggH theoretical inputs fine, still work on the experimental side to fully implement it
 VBF to be worked out (hopefully some proposal from CMS in the next weeks)
 EWsinglet
 reasonable LO strategy discussed today
 a NLO precision can be reached by ~Fall > we should contact the BR group immediately to ask to implement it in Prophecy4f (G.Passarino and C.Grojean)
 2HDM
 low mass at LO: ATLAS has some preliminary work ongoing, will be presented at next meeting and hopefully documented in YR3. We should also contacts theoreticians involved in 2HDM and ask to present at next meeting (K.Peters)
 high mass and NLO needs more work. Similar problem as in the SM case but mroe complex:
 plan to implement it in gg2VV (N.Kauer)
 EWK correction at NLO to be computed analytically (G.Passarino/all)
 VV scattering: we should start to discuss how to organize the work during LS1
Proposal to start with mini workshop inviting experts (eg, Phantom authors)
Plans for YR3:
 Heavy Higgs SM case pretty well documented (contribution for VBF case can be added if study will be done in time)
 EWsinglet:
 draft document has been circulated, it can be cleanedup and included directly
 CMS studies with MCFM and gg2VV can be added
 2HDM: hopefully some preliminary studies from ATLAS (to be shown at next meeting)
Minutes of Heavy Higgs  BSM Group (23rd January 2013)
Link to the agenda
 Introductory talk with proposed strategy for BSM Heavy Higgs (SM Higgs with mixing with EW singlet) > many questions in the slides. Summary of the discussion and open questions to follow up:
 BRnew = 0 is something reasonable? Is the effect on the width of the decay H>hh negligible ?
 QCD corrections in this BSM model are the same as in the SM (so same xsec uncertainty and pt spectrum)
 EW corrections may be different but small wrt QCD corrections > strategy for interference uncertainty with K and K' as in the SM is still applicable? Are K and K' different in this BSM models wrt to SM?
 Interference is proportional to the total width so:
 if BRnew=0, total width in this BSM model is equal to the SM total width, then S+I = S_SM * cosTheta^2 + I_SM * cosTheta
 if BRnew>0 the total width will change wrt SM and I/S will scale differently
 SM searches stop at 1 TeV (where mH/Gamma = 1 TeV / 0.7 TeV) > Can we stop the BSM search at the mH/Gamma' = 1/0.7 as well? (in BSM we will have a different mH value for each width) (In SM 1 TeV is put as limit for unitarization constraints, the unitarization problems are pushed to higher values in this BSM model since the low mass Higgs performs already most of the unitarization)
 CMS talk with proposed strategy: rescale CPS lineshape with different width + interference from MCFM with different width rescales. Summary of the discussion:
 interference reweighting:
 plan A: uncertainty from K,K' rescaling as in the SM case
 plan B: correct for interference from MCFM and put 100% uncertainty on this
 plan C (not optimal): do not reweight for the interference, but put a limit equal the SM interference value that is the worse case. NB. It is not optimal since we know how much the interference is, so we should correct for it
 we need the table of interference values for each value of width and mH (we can also just scale from the SM case as shown in slide 8 right, would be the uncertainty enough to cover the discrepancy between simple SM rescaling and proper interference computation?)
 ATLAS talk with general issues. Summary of the discussion:
 the interference between gg>WW and gg>ZZ in same final state (lnln) needs to be better studied > manpower!
 the interference between VBF signal and VV scattering needs to be better studied > manpower!
 both the previous issues are under study in the SM case (and we have preliminary numbers/recipe), more studies are welcome.
 in this BSM LHCXS working subgroup we are targeting very specific models which are direct extensions of the SM case so the proper recipe for the SM case needs to be implemented as first, both in ggF and VBF
These specific models also have direct connection with the already discovered low mass Higgs > common fit to low mass couplings and high mass search
Generic and modelindependent bump hunt (eg useful for graviton search) are outside the scope of the group.
Minutes of Heavy Higgs  BSM Group (12th October 2012)
Link to the agenda
 proposal for HCP strategy presented and accepted: reweigthing for CPS and interference in mVV spectrum (see slides for full details)
 studies of interference effect in WW>lnjj: mWW reweigthing is enough to give the correct shape to other distributions (xchecked with MCFM)
Uncertainty due to missing higher orders in interference are applied both to the mVV shape and to the total normalization
 proposal to study interference in VBF using Phantom and Madgraph.
 We should also compare with VBF@NLO [full offshell, only tchannel, but at NLO] [Andre will contact VBF@NLO authors]
 We should also contact Dittmaier group which shown results about this in the past [Sara will do this]
Minutes of BSM and Heavy Higgs Meeting (27th July 2012)
This has been a meeting between the contact person to rumpup after the ICHEP rush and plan for the next open meeting (coming soon)
Interference for heavy Higgs:
 ZZ recipe settled, trying to develop a recipe for WW (see slides from Sara D.)
 proposal:
 gg2VV generate S, B, S+B+I > extract S+I by subtracting distribution of (S+B+I)  B
 rescale to NLO with kfactors from Passarino (already provided)
 objection:
 the NLO affects more distributions than what a kfactor may describe
 interference is much bigger than in ZZ and it affects many distributions (while you extract S+I you can do only for one or few distributions at once) * answer:
 kfactor mainly affects pT (if w/o cuts) and it should be fine for inclusive case (we have to check for +1,2 jets) and if need to rescale more distribution we can contact the HRes people
 let's start looking at ggVV and MCFM and MC@NLO for additive case, compare and validate and then we go ahead from there * question: does CMS/ ATLAS simulate ggVV background or does it datadriven way? we need to have it simulated in order to implement any recipe
 CMS: yes for H>ZZ>4lep, H>WW>lnln, not for semileptonic final states and H>ZZ>2l2n (to be checked)
 ATLAS: the same
 Next step: define benchmarks compatible with low mass observation. Discussion:
 in models where the low mass Higgs unitarizes only partially the VV amplitude, there is an heavier resonance which share the couplings to VV. This heavier resonance must interfere with VV similarly to the SM case (but interference suppressed wrt to Heavy SM Higgs as couplings suppressed)
 Useful things to discuss at next open meeting:
 update from the theoreticians about sensible benchmark models after low mass discovery: should include heavy resonance cases as well as benchmark related with present and possible future measurements of the couplings for the observed low mass state (see below)
 report from experimentalist about plans for VV high mass searches (some activity in CMS)
 The measuring of the observed resonance couplings is done in the LowMass group but they have a very model independent approach, we can be nicely complementary by proposing some specific models to test against the couplings measurement. (We should explicitly invite LM people at the next meeting)
 Define benchmark is a nice thing but what about MC ? Experimentalists need MC for specific models in order to test them
VV scattering
To be handled in strict collaboration with VBF group.
CMS/ATLAS have interest in this but not enough manpower now for a full analysis
Minutes of Heavy Higgs Meeting (7th June 2012)
Summary about lineshape
 Inclusive Xsec
 ggF numbers at 8 TeV with complex pole included are ready
 ggF numbers at 7 TeV with complex pole included will arrive soon
 effect on VBF xsec is taken into account from M>300 GeV for 8 TeV.
 the residual theoretical uncertainty just due to line shape is much smaller than PDF and scale uncertainty (we will neglect it)
 Higgs mass lineshape (valid for all final states)
 central values with complex pole available here and also implemented in POWHEG routine to reweigh our MC samples
 uncertainty up and down bin by bin also available here and to be applied as residual systematics for the line shape
 this applies both to ggF and VBF
Interference for H>ZZ
 Inclusive xsec: effect has been proven to be very small (<1%) just neglect it
 Effect on mH shape is much bigger (constructive below the peak and destructive above the peak).
Let's define K=signal NNLO / signal LO. We have 3 approaches to include NNLO effects into signal, in presence of interference:
 multiplicative: (S+I)*K + B
 additive: S*K + I + B
 intermediate: S*K + I*K' + B Where K' is the square root of (signal NNLO/ signal LO) but considering only the gg initiated final states (not qg or qq). THIS IS NOT SUPPOSED TO BE A CORRECT COMPUTATION, this is just something reasonable which is always in between the other two approaches by construction
THIS IS THE ACCEPTED RECIPE

 central values from the intermediate recipe (the bullet 3. above)
 uncertainty are taken as the FULL ENVELOPE of multiplicative and additive (i.e. the full difference btw bullets 1 and 2 above). This corresponds to take 100% uncertainty on the K factor used to scale the interference
 the full list of numbers is mh400, mh500, mh600, mh700, mh800
 example of some plots with line shape and uncertainty band here
Comments/discussion
 the important point is to take the full difference btw multiplicative and additive as uncertainty. Then we have a good degree of belief that the "right" answer is in between them. Let's take the intermediate recipe as central value just as a reasonable approximation.
 on top of this we will need to check the effect of the NLO effects on the interference for the full kinematical distributions (not only the line shape but all the others distribtions). The effect is expected to be small in 4lep analysis, this should be checked but doable only after ICHEP
Interference for H>WW
 the interference has been proven to have huge effect both on xsec and on all the kinematical distributions
 the only way to check/correct for it would be to run gg2WW or MCFM
 we will never be able to do it in time for ICHEP
 SO THIS IS THE ACCEPTED RECIPE: let's stick to the 2011 recipe, i.e. we put a huge uncertainty on the xsec computed as 1+ (1.5*MH/TeV)^3 AND WE STOP THE SEARCH AT 600 GeV AS LAST YEAR
Minutes of Heavy Higgs  BSM Group (11th May 2012)
Link to the agenda
Doublycharged Higgs. See slides for an overview of the status. Comments:
 the bound on vev is not strict (cancelation between different contributions to Delta rho are always possible), the VBF xsec should be parametrized as a function of vev
 Next step:
 experiments should define their interest in expanding this search and present the needs/proposals at the workshop 2425 May to get feedback from theoreticians
 the proposal will be prepared/discussed in dedicated BSM meetings btw the relevant contact person and the interested analyzers
 ATLAS plan: paper with fiducial xsec in multi lepton and then conference notes on specific models
Fermiophobic Higgs. See slides for a proposal of benchmark
 basic/simple FP model in not fully consistent/valid as specific model.
 proposal is to have parametrization of the relative couplings with fermions and with bosons with reasonable boundaries as a function of mH. This should be the simplest toy model which is fully consistent (e.g., radiative corrections may be computed)
 the coupling of the charged Higgs to gamma gamma should also be taken under control
 similar parametrization proposed in the paper from Azatov et al [arXiv:1202.3415] and Espinosa et al [arXiv:1202.3697] (a=coupling to V, c=coupling to f and then a=c=1 is SM while a=1 and c=0 is simple FP). In the slides the explicit relation btw these 2 parameters is shown and a way to bound them to realistic values as a function of mH
 these modified couplings have been implemented in hdecay and the code, once validated by the various people involved, will be made publicly avaiable
BSM items for 24,25th workshop
 double charged Higgs
 FP Higgs
 a0 (to be followed up with MSSM people)
 general inventory presented at the previous meeting to have feedback
 the various topics will be followed up in separate meetings with interested people
Heavy Higgs
Heavy Higgs: reweighing for lineshape
 Easytouse tool available to implement the complexpolescheme (arXiv:1112.5517) in powheg samples
 this reweighing is orthogonal to the interference effects (it depends only on Higgs virtuality m). Can be applied on top of any interferencerelated reweighting.
 the line shape affect also the total xsec. This can be recalculated with POWHEG itself or the NNLO+NNLL xsec can be corrected for the effect (in any case the NNLO+NNLL xsec agrees with POWHEG xsec)
 uncertainty on the total xsec due to lineshape uncertainty as well as shape uncertainty itself can be provided by Passarino. Should be easy to extend the POWHEG tool to include it.
 Experience of reweighing for lineshape in the VBF group
 similar approach developed in the VBF group: starting directly from numbers provided by Passarino for the complexpolescheme to reweight HAWK (include EWK effects)
 the plots of the shape (w/0 EWK corrections) agree with POWHEG but there is a mismatch in the overall xsec (to be followed up offline)
 The reweighting of POWHEG is very useful to recompute all the acceptance effects in the experiments. And having 2 tools allow further comparisons/xchecks
 The EWK corrections should be completely negligible in ggF and a global kfactor should good enough in VBF
HeavyHiggs items for the May 2425 workshop
 would be good to have some results from experiments (e.g., effect on acceptance) due to line shape rewieghting
 interference in ZZ>2l2n in gg2ZZ MC may be ready soon!
 summary of the 1415 CERN workshop (to be prepared by Sara&Sara)
Minutes of Heavy Higgs  BSM Group (30th April 2012)
Link to the agenda
BSM inventory:
List of the present Higgs BSM searches ongoing in the 2 experiments. Comments:
 4th generation: Babis comment: theory breaks when q' mass >500 GeV (and direct serach is excluding lower q' mass). Does it still make sense to consider this model?
 Doubly charged Higgs: signal kfactor is taken from NLO calculations (also in the ATLAS result, apologies for the confusion)
 Fermiophobic Higgs: only a benchmark model. Theoretically not well defined, need to discuss how this should be addressed by experiments.
 Searches for a light CPOdd Higgs (dedicated MC is needed)
Review of the theoretical models. Comments
 All what is a "simple" extension of the SM Higgs should be dealed in strict collaboration with the "Properties measurement" group: the aim is to extract limits leaving floating as many parameters as possible and removing SM costraints wherever possible.
 Similarly, the SUSY Higgs is splitted between MSSM/BR groups and this BSM group (NMSSM, XMSSM, ...). We should try to setup a joint meeting in the next future.
 For next iteration:
 list of detailed "needs" and open issue from experimentalists concerning the listed BSM analyses
 list of theoretical models which are not looked at and suggestions how to present results in more general way (such that can be reinterpreted in different models)
Heavy Higgs
 We should identify list of high mass BSM models which are compatible with observed xsec limits. In parallel we can pursue an openmind approach with a general serach for spin 0 or spin 1 resonance at very high mass.
 2 stages:
 before any discover of light higgs
 after that (if any) Main aim should be to measure exactly the VV xsec (and in case 2) see if it is compatible with the presence of a light higgs boson)
 Heavy SMlike Higgs cannot exist without new physics
Lineshape and interference
 A description of the correct lineshape for signal has been proposed and it si available. Now is necessary to implement the interference in the same scheme (almost ready in aMC@NLO!). Alternative descriptions should come soon
The difference in lineshape observed for different scheme should not be considered a theoretical uncertainty
 for VBF case everything is properly implemented in the WWjj and ZZjj production processes in VBFNLO
 MC@NLO: alternative approach based on effective theory which deals with resonant and notresonant pieces in such a way to mitigate the gaugeinvariance problems. This will allow to produce events and applying cuts.
 2 approaches on the table. What if any of them is ready for ICHEP? Is it feasible to reweight separately for the lineshape and the interference effects?
Review of MC containing ZZ/WW interferences
gg2ZZ. Comments
 CMS collaboration is already using the code to produce massive amount of events
 BW with fixed width
aMC@NLO. Comments
 they can also implement the interference effects btw the 2 Zeds in the 4e and 4mu final state
MCFM. Comments
 No top mass in gg>ZZ computation so interference would not be reliable.
 The Seymour scheme developed for s>infinity may not be reliable for low value of s
 WW is ok (but not correct line shape) can be used to reweigh the distributions (but NLO effects on interference are anyway missing and they can be large as well)

SaraBolognesi  11May2012