A list of things:
References
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Higgs Interference Effects in $\Pg\Pg \to \PZ\PZ$ and their Uncertainty;
Author: G. Passarino;
Published in JHEP 1208 (2012) 146
DOI: 10.1007/JHEP08(2012)146
e-Print: arXiv:1206.3824 [hep-ph]
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The Higgs Boson Lineshape
Author: S. Goria, G.Passarino and D.Rosco;
Published in Nucl.Phys. B864 (2012) 530-579
DOI: 10.1016/j.nuclphysb.2012.07.006
e-Print: arXiv:1112.5517 [hep-ph]
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Higgs Pseudo-Observables, Second Riemann Sheet and All That
Author: G. Passarino, C. Sturm and S. Uccirati;
Published in Nucl.Phys. B834 (2010) 77-115
DOI: 10.1016/j.nuclphysb.2010.03.013
e-Print: arXiv:1001.3360 [hep-ph]
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New
I received urgent requests for heavy Higgs lineshape results
(to reweight MCs and to allow for extension of searches above 600 GeV).
ut mihi videtur, ille vigor naturalis est Teoria Unitaria,
id est divina et benigna concordia que est id a quo omnia
habent esse, moveri, crescere, sentire, vivere, discernere.
Last added: May 16 2012
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Here you will find the full paper, including THU
for the signal lineshape
download,
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Here you will find my notes for the
BSM Subgroup kickoff meeting, Monday, April 30, 2012
download,
Last added: September 1 2012
- Here you will find data for the lineshape THU at 8 TeV
Legenda,
OFFP Central values,
OFFP value 1,
OFFP value 2,
BW Central values,
- Here you will find data for the interference at 8 TeV
Last added: September 1 2012
Summary of data, Numerics updated
effective NNLO, legenda,
effective NNLO at 400 GeV, Summary,
effective NNLO at 420 GeV, Summary,
effective NNLO at 425 GeV, Summary,
effective NNLO at 440 GeV, Summary,
effective NNLO at 450 GeV, Summary,
effective NNLO at 460 GeV, Summary,
effective NNLO at 475 GeV, Summary,
effective NNLO at 480 GeV, Summary,
effective NNLO at 500 GeV, Summary,
effective NNLO at 520 GeV, Summary,
effective NNLO at 525 GeV, Summary,
effective NNLO at 540 GeV, Summary,
effective NNLO at 550 GeV, Summary,
effective NNLO at 560 GeV, Summary,
effective NNLO at 575 GeV, Summary,
effective NNLO at 580 GeV, Summary,
effective NNLO at 600 GeV, Summary,
effective NNLO at 650 GeV, Summary,
effective NNLO at 700 GeV, Summary,
effective NNLO at 750 GeV, Summary,
effective NNLO at 800 GeV, Summary,
effective NNLO at 850 GeV, Summary,
effective NNLO at 900 GeV, Summary,
effective NNLO at 950 GeV, Summary,
effective NNLO at 1000 GeV, Summary,
effective NNLO at 700 GeV and 8 TeV, Summary,
effective NNLO at 700 GeV and 7 TeV, Summary,
Paper
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Paper on Interference,
Last added: September 1 2012
Summary of K factors
Bins - K - sqrt(Kgg)
K - factors at 400 GeV, Summary,
K - factors at 420 GeV, Summary,
K - factors at 425 GeV, Summary,
K - factors at 440 GeV, Summary,
K - factors at 450 GeV, Summary,
K - factors at 460 GeV, Summary,
K - factors at 475 GeV, Summary,
K - factors at 480 GeV, Summary,
K - factors at 500 GeV, Summary,
K - factors at 520 GeV, Summary,
K - factors at 525 GeV, Summary,
K - factors at 540 GeV, Summary,
K - factors at 550 GeV, Summary,
K - factors at 560 GeV, Summary,
K - factors at 575 GeV, Summary,
K - factors at 580 GeV, Summary,
K - factors at 600 GeV, Summary,
K - factors at 650 GeV, Summary,
K - factors at 700 GeV, Summary,
K - factors at 750 GeV, Summary,
K - factors at 800 GeV, Summary,
K - factors at 850 GeV, Summary,
K - factors at 900 GeV, Summary,
K - factors at 950 GeV, Summary,
K - factors at 1000 GeV, Summary,
Last added: September 19 2012
Wide scan:
600 - 700 GeV stops at 1.8 TeV
650 - 1000 GeV stops at 2 TeV
Results produced on September 2012 with HTO. Legenda:
Complex-Pole-Scheme (OFFP - scheme of arXiv:1112.5517)
Lineshape - CPS including NLO EW and G_top and dynamical QCD scales
+/- errors as described in Sect. 7 of arXiv:1112.5517
they include THU but not QCD scales, nor PDF, nor alpha_s
error minus = central - min(value_1,value_2)
error plus = max(value_1,value_2) - central
LS at 600 GeV, Central,
LS at 600 GeV, value_1,
LS at 600 GeV, value_2,
LS at 650 GeV, Central,
LS at 650 GeV, value_1,
LS at 650 GeV, value_2,
LS at 700 GeV, Central,
LS at 700 GeV, value_1,
LS at 700 GeV, value_2,
LS at 750 GeV, Central,
LS at 750 GeV, value_1,
LS at 750 GeV, value_2,
LS at 800 GeV, Central,
LS at 800 GeV, value_1,
LS at 800 GeV, value_2,
LS at 850 GeV, Central,
LS at 850 GeV, value_1,
LS at 850 GeV, value_2,
LS at 900 GeV, Central,
LS at 900 GeV, value_1,
LS at 900 GeV, value_2,
LS at 950 GeV, Central,
LS at 950 GeV, value_1,
LS at 950 GeV, value_2,
LS at 1000 GeV, Central,
LS at 1000 GeV, value_1,
LS at 1000 GeV, value_2,
K factors for ZZ up to 2 TeV
K factors for ZZ ,
Interference factors
In the following tables you will find I = Total/(Signal + Background) - 1 [%]
estimated with HTO, where Total = Signal + Interference + Background
for gg --> ZZ. Therefore, you can take
(Signal + Background)_your and get Interference_your
Format is
bin[5 GeV] / I [%] / - Delta I [%] / + Delta I [%]
effective NNLO at 600 GeV, Summary,
effective NNLO at 650 GeV, Summary,
effective NNLO at 700 GeV, Summary,
effective NNLO at 750 GeV, Summary,
effective NNLO at 800 GeV, Summary,
effective NNLO at 850 GeV, Summary,
effective NNLO at 900 GeV, Summary,
effective NNLO at 950 GeV, Summary,
effective NNLO at 1000 GeV, Summary,
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Disclaimer
There are plenty of indications that it is very difficult
for an heavy Higgs boson to come out right within the SM.
I should not be held responsible for the consequences.
Last modified September 19, 2012