Diffractive Higgs production at the LHC

1. p H p Diffractive Higgs production at the LHC Alan Martin (Durham) October 2007

2. Exclusive Higgs production at the LHC Khoze, Martin, Ryskin O(1 GeV) ? far from IP The price for rapidity gaps ? 

4. calculated from multi-Pomeron multi-channel eikonal analysis of soft pp data S2 = 0.02 at LHC S2 = 0.05 at Tevatron no emission when (l ~ 1/kt) > (d ~ 1/Qt) i.e. only emission withkt > Qt

5. = + + + …. Description of ‘soft’ high energy pp interactions DL: aeff = 1.08 + 0.25t ---but nothing about inelastic intn Inclusion of multi-P effects essential: new analysis N* KMR 2007 abare ~ 1.5 + 0t + + + …. full multi-Pomeron 2-ch eikonal where stotal(LHC) ~ 90 mb S2Higgs(LHC) ~ 0.02

7. Prediction of s(pp p + H + p) contain Sudakov factor Tg which exponentially suppresses infrared Qt region  pQCD H S2 is the prob. that the rapidity gaps survive population by secondary hadrons  soft physics  S2=0.02 (LHC) S2=0.05 (Tevatron) s(pp  p + H + p) ~ 3 fb at LHC for SM 120 GeV Higgs ~0.2 fb at Tevatron

8. s(ppp+H+p) ~ 3 fb at LHC for 120 GeV Higgs if L = 60 fb-1, then 180 events efficiency of p taggers 54 BR(Hbb) 36 b,b tag efficiency 18 polar angle cut 9 mass window 6 events

9. Background to ppp + (Hbb) + p signal assuming DMmiss ~ 3sM ~ 5 GeV B/S LO (=0 if mb=0, forward protons) gg  gg mimics gg  bb (P(g/b)=1.3%) after polar angle cut  0.3 Irreducibe bb  0.5 HO (gg)col.sing bb+ng Soft emissions still suppressed by Jz=0  ~ 0 Hard emissions if g not seen: extra gluon along beam Mmiss > Mbb ~0 extra g from initial g along b or b 0.2 Pomeron-Pomeron inelastic0.06 for M=120 GeV total B/S~1 S~1/M3, B~DM/M6 : triggering, tagging, DM better with rising M

10. signal backgd hard P 150 20 70 5 soft P ds/dy|y=0 units 10-3 fb kT<5 GeV DMdijet/Mbb=20% DMmissing=4GeV 9 0.14

11. conventional signal for SM 110-130 GeV Higgs

12. enhanced eikonal S2 =0.02 BBKM. (first) corrn could be large and -ve,

13. BBKM  (first) corrn could be large and -ve,

14. BBKM (pQCD analysis) find first corrn could be large and –ve. BUT…need to sum complete set of diagrams. terms alternate in sign Amp 70% sum Analogous new “soft” non-perturbative analysis finds that even at low QT, amp. is not completely suppressed QT~2GeV ln QT2 1st term corrn affects mainly small QT (large size dipoles)

15. New global fit to “soft” data The full set of enhanced diag. are included in stot, sSD … in global soft fit The fit to “soft” data including enhanced rescatt. --redistributes abs. effects between eik. and enh. --find total S2 same Analogously predn for stot(LHC) has v.weak model dep. since model fits existing soft data and there is log s energy behaviour sSD, sensitive to enh. effects, ~flat from 100 GeV, so expect no extra suppression of diffraction at LHC

16. Leading neutron prod. at HERA g g g KKMR ‘06 gap due to p exchange ~ exclusive Higgs eikonal “enhanced” yi > 2 – 3 correction prop. to rap. interval prop. to g energy (negative) Prob. to observe leading neutron must decrease with g energy But expt.  flat  small enhanced correction g g g g seen not seen

17. Level 1 trigger 420 220 220 420 veto veto veto-trigger spoiled by pile-up 420-trigger spoiled by c ------------- buffer ? At present, plan to use 2 high ET jets/m + 220 (+ 420) +…?

18. LHC every bunch crossing ! Note N = 3.5  1.7 N = 35  17 as above numbers include elastic and low mass inelastic in pile-up

19. ~0.01N for 420m ~0.03N for 220m Note: much recent progress (Tasevsky, Cox, Brandt,….) using timing, dijet 4-mom = missing 4-mom., checking multiplicity transverse to b jets, etc….much more optimistic

20. SUSY Higgs: h, H, A, (H+, H--) There are parameter regions where the pp  p + (h,H) + p signals are greatly enhanced in comparison to the SM Selection rule favours 0++ diffractive production

22. decoupling regime: mA ~ mH > 150 h ~ SM bbH ~ tanb VVH ~ 0 H,A tt (bb) intense coup: mh ~ mA ~ mH gg,WW.. coup. suppressed

23. exclusive signal 5s signal at LHC 100 fb-1

24. Adapted from a preliminary plot of Tasevsky et al. (HKRSTW)

25. Possible checks of exclusive rates at the Tevatron “standard candles” at Tevatron to test excl. prod. mechanism ppp + c + p high rate, but only an ord.-of-mag.estimate ppp + jj + p rate OK, but jet algorithm, hadronization etc ppp + gg + p low rate, but cleaner signal “standard candles”

26. ppp + gg + p KMR+Stirling

27. Measurements with Mgg=10-20 GeV could confirm sH(excl) prediction at LHC to about 20% or less

28. CDF Blessed this morning! one appears due to p0gg CDF, Albrow et al. 3 events observed 16 events observed ~0.09pb ~0.04pb It means exclusive H must happen (if H exists) and probably ~ 10 fb within factor ~ 2.5. higher in MSSM QED: LPAIR Monte Carlo s(gg) = 10 fb for ETg>14 GeVat LHC

29. 16 events were like this: Albrow 3 events were like this: one appears due to p0gg

30. Exptally more problematic due to hadronization, jet algorithms, detector resolution effects, QCD brem… ppp + jj + p Exclusive events have Rjj = Mjj/MX =1, but above effects smear out the expected peak at Rjj = 1(ExHuME MC) sexcl~Rjj>0.8 sexcl(M>Mjj)

31. Conclusion The ppp+H+p cross section prediction is robust----factor 2 S/B~1 for SM h -----can be more for SUSY h, H. Checks are starting to come from Tevatron data (gg,dijet…) There is a strong case for installing proton taggers at the LHC, far from the IP ---- it is crucial to get the missing mass DM of the Higgs as small as possible. Need more exptal and theoretical work on L1 trigger The diffractive Higgs signals beautifully complement the conventional signals. Indeed there are SUSY Higgs regions where the diffractive signals are advantageous ---determine DMH, Yukawa Hbb coupling, 0++ ---searching for CP-violation in the Higgs sector