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META TOPICPARENT name="Higgs2Tau"

Evidence for the 125 GeV Higgs boson decaying to a pair of $\tau$ leptons

This is a condensed description with plots for the analysis CMS-HIG-13-004

Table of contents:

Abstract

A search for a standard model Higgs boson decaying into a pair of $\tau$ leptons is performed using events recorded by the CMS experiment at the LHC in 2011 and 2012. The dataset corresponds to an integrated luminosity of 4.9 $fb^{-1}$ at a centre-of-mass energy of 7 TeV and 19.7 $fb^{-1}$ at 8 TeV. Each $\tau$ lepton decays hadronically or leptonically to an electron or a muon, leading to six different final states for the $\tau$-lepton pair, all considered in this analysis. An excess of events is observed over the expected background contributions, with a local significance larger than 3 standard deviations for $m_{\rm H}$ values between 115 and 130 GeV. The best fit of the observed $H \rightarrow \tau \tau$ signal cross section for $m_{H} = 125$ GeV is $0.78 \pm 0.27$ times the standard model expectation. These observations constitute evidence for the 125 GeV Higgs boson decaying to a pair of $\tau$ leptons.

Figures from CMS-HIG-13-004

png pdf Figure 1: Leading-order Feynman diagrams for Higgs boson production through gluon-gluon fusion (left), vector boson fusion (middle), and the associated production with a W or a Z boson (right).
png pdf Figure 2: Observed and predicted distributions for the visible $\tau$ mass, $m_{vis}^{\tau_h}$, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the $Z\rightarrow\tau\tau$, $Z\rightarrow\mu\mu$, electroweak, $t\bar{t}$, and QCD multijet background contributions correspond to the result of the final fit. The $Z\rightarrow\tau\tau$ contribution is then split according to the decay mode reconstructed by the hadron-plus-strips algorithm as shown in the legend. The mass distribution of the $\tau$ built from one charged hadron and photons peaks near the mass of the intermediate $\rho(770)$ resonance; the mass distribution of the $\tau$ built from three charged hadrons peaks around the mass of the intermediate $a_1(1260)$ resonance. The $\tau$ built from one charged hadron and no photons are reconstructed with the $\pi^\pm$ mass, assigned to all charged hadrons by the PF algorithm, and constitute the main contribution to the third bin of this histogram. The first two bins correspond to $\tau^{\pm}$ leptons decaying into $e^{\pm}\nu\nu$ and $\mu^{\pm}\nu\nu$, respectively, and for which the electron or muon is misidentified as a $\tau$. The electroweak background contribution is dominated by $W+jets$ production. In most selected $W+jets$, $t\bar{t}$, and QCD multijet events, a jet is misidentified as a $\tau$. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure 3a: Normalized distributions obtained in the $\mu\tau_h$ channel after the baseline selection for the invariant mass, $m_{vis}$, of the visible decay products of the two $\tau$ leptons. The distribution obtained for a simulated sample of $Z\rightarrow\tau\tau$ events (shaded histogram) is compared to the one obtained for a signal sample with a SM Higgs boson of mass $m_H=125$ GeV (open histogram).
png pdf Figure 3b: Normalized distributions obtained in the $\mu\tau_h$ channel after the baseline selection for the SVFit mass, $m_{\tau\tau}$. The distribution obtained for a simulated sample of $Z\rightarrow\tau\tau$ events (shaded histogram) is compared to the one obtained for a signal sample with a SM Higgs boson of mass $m_H=125$ GeV (open histogram).
png pdf Figure 4: Event categories for the $LL'$ channels. The $p_T^{\tau\tau}$ variable is the transverse momentum of the Higgs boson candidate. In the definition of the VBF-tagged categories, $\Delta\eta_{jj}$ is the difference in pseudorapidity between the two highest-$p_T$ jets, and $m_{jj}$ their invariant mass. In the $ee$ and $\mu\mu$ channels, events with two jets are not required to fulfil any additional VBF tagging criteria. For the analysis of the 7 TeV $e\tau_h$ and $\mu\tau_h$ data, the loose and tight VBF-tagged categories are merged into a single VBF-tagged category. In the $e\tau_h$ channel, the MET is required to be larger than 30 GeV in the 1-jet category. Therefore, the high-$p_T^{\tau}$ category is not used and is accordingly crossed out.
png pdf Figure 5a: Observed and predicted distributions in the $\mu\tau_h$ channel after the baseline selection, for the transverse momentum of the Higgs boson candidates. The yields predicted for the various background contributions correspond to the result of the final fit. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. In each plot, the bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure 5b: Observed and predicted distributions in the $\mu\tau_h$ channel after the baseline selection, for the transverse momentum of the $\tau$. The yields predicted for the various background contributions correspond to the result of the final fit. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. In each plot, the bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure 6: Observed and predicted $m_T$ distribution in the 8 TeV $\mu\tau_h$ analysis after the baseline selection but before applying the $m_T<30$ GeV requirement, illustrated as a dotted vertical line. The dashed line delimits the high-$m_T$ control region that is used to normalize the yield of the $W+jets$ contribution in the analysis as described in the text. The yields predicted for the various background contributions correspond to the result of the final fit. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from a SM Higgs signal is negligible.
png pdf Figure 7: Observed and predicted distribution for the number of jets in the 8 TeV $e\mu$ analysis after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit. The electroweak background contribution includes events from diboson and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from a SM Higgs signal is negligible.

Mass / Final Discriminator Distributions at 8 TeV

png pdf Figure 8a: Observed and predicted SVFit mass distributions in the $\mu\tau_h$ channel, and in the 1 jet, high $p_T^{\tau}$, medium $p_T^{\tau\tau}$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 8b: Observed and predicted SVFit mass distributions in the $\mu\tau_h$ channel, and in the loose VBF category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 8c: Observed and predicted SVFit mass distributions in the $\mu\tau_h$ channel, and in the tight VBF category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 8d: Observed and predicted SVFit mass distributions in the $e\tau_h$ channel, and in the 1 jet, high $p_T^{\tau}$, medium $p_T^{\tau\tau}$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 8e: Observed and predicted SVFit mass distributions in the $e\tau_h$ channel, and in the loose VBF category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 8f: Observed and predicted SVFit mass distributions in the $e\tau_h$ channel, and in the tight VBF category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 9a: Observed and predicted SVFit mass distributions in the $\tau_h\tau_h$ channel, and in the 1 jet, medium $p_T^{\tau\tau}$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 9b: Observed and predicted SVFit mass distributions in the $\tau_h\tau_h$ channel, and in the 1 jet, high $p_T^{\tau\tau}$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 9c: Observed and predicted SVFit mass distributions in the $\tau_h\tau_h$ channel, and in the VBF category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 9d: Observed and predicted SVFit mass distributions in the $e\mu$ channel, and in the 1 jet, high $p_T^{\tau}$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The expected contribution from $HWW$ decays is shown separately. The signal and background histograms are stacked.
png pdf Figure 9e: Observed and predicted SVFit mass distributions in the $e\mu$ channel, and in the loose VBF category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The expected contribution from $HWW$ decays is shown separately. The signal and background histograms are stacked.
png pdf Figure 9f: Observed and predicted SVFit mass distributions in the $e\mu$ channel, and in the tight VBF category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The expected contribution from $HWW$ decays is shown separately. The signal and background histograms are stacked.

png pdf Figure 10a: Observed and predicted D distributions in the $\mu\mu$ channel, for the 0 jet, high $p_T^{\mu}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 10b: Observed and predicted final discriminator D distributions in the $\mu\mu$ channel, and in the 1 jet, high $p_T^{\mu}$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 10c: Observed and predicted final discriminator D distributions in the $\mu\mu$ channel, and in the 2 jets category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.

png pdf Figure 10d: Observed and predicted D distributions in the $ee$ channel, for the 0 jet, high $p_T^{e}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 10e: Observed and predicted final discriminator D distributions in the $ee$ channel, and in the 1 jet, high $p_T^{e}$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 10f: Observed and predicted final discriminator D distributions in the $ee$ channel, and the 2 jets category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.

png pdf Figure 13a: Observed and predicted $m_{vis}$ distributions in the $l+l'\tau$ channel in the low-$L_T$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction ($\mu = 1$). The signal and background histograms are stacked.
png pdf Figure 13b: Observed and predicted $m_{vis}$ distributions in the $l+l'\tau$ channel in the high-$L_T$ category. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction ($\mu = 1$). The signal and background histograms are stacked.
png pdf Figure 13c: Observed and predicted $m_{vis}$ distributions in the $l+\tau\tau$ channel. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction ($\mu = 1$). The signal and background histograms are stacked.
png pdf Figure 13d: Observed and predicted $m_{tautau}$ distributions in the $ll + LL'$ channel. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction ($\mu = 1$). The signal and background histograms are stacked.

Results

png pdf Figure 11: Combined observed and predicted $m_{\tau\tau}$ distributions for the $\mu\tau_h$, $e\tau_h$, $\tau_h\tau_h$, and $e\mu$ channels. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction ($\mu = 1$). The distributions obtained in each category of each channel are weighted by the ratio between the expected signal and signal-plus-background yields in the category, obtained in the central $m_{\tau\tau}$ interval containing 68% of the signal events. The inset shows the corresponding difference between the observed data and expected background distributions, together with the signal distribution for a SM Higgs boson at $m_{H}=125$ GeV. The distribution from SM Higgs boson events in the $WW$ decay channel does not significantly contribute to this plot.
png pdf Figure 12: Local $p$-value and significance in number of standard deviations as a function of the SM Higgs boson mass hypothesis for the $LL'$ channels. The observation (solid line) is compared to the expectation (dashed line) for a SM Higgs boson with mass $m_H$. The background-only hypothesis includes the $pp\rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$.
png pdf Figure 14a: Combined observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure 14b: Combined observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{\rm SM}$, together with the expected limit obtained in the signal-plus-background hypothesis for a SM Higgs boson with $m_{H}=125$ GeV. The background-only hypothesis includes the $pp\rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure 15: Local $p$-value and significance in number of standard deviations as a function of the SM Higgs boson mass hypothesis for the combination of all decay channels. The observation (solid line) is compared to the expectation (dashed line) for a SM Higgs boson with mass $m_H$. The background-only hypothesis includes the $pp\rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$.
png pdf Figure 16a: Best-fit signal strength values, for independent channels, for $m_H = 125$ GeV. The combined value for the $H\rightarrow\tau\tau$ analysis in both plots corresponds to $\hat{\mu}$, obtained in the global fit combining all categories of all channels. The dashed line corresponds to the best-fit $\mu$ value.The contribution from the $pp\rightarrow H_{(125~GeV)}\rightarrow WW $ process is treated as background normalized to the SM expectation.
png pdf Figure 16b: Best-fit signal strength values, for independent categories, for $m_H = 125$ GeV. The combined value for the $H\rightarrow\tau\tau$ analysis in both plots corresponds to $\hat{\mu}$, obtained in the global fit combining all categories of all channels. The dashed line corresponds to the best-fit $\mu$ value. The contribution from the $pp\rightarrow H_{(125~GeV)}\rightarrow WW$ process is treated as background normalized to the SM expectation.
png pdf Figure 17: Combined observed and predicted distributions of the decimal logarithm $\log(S/(S+B))$ in each bin of the final $m_{\tau\tau}$, $m_{vis}$, or discriminator distributions obtained in all event categories and decay channels, with $S/(S+B)$ denoting the ratio of the predicted signal and signal-plus-background event yields in each bin. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction ($\mu = 1$). The inset shows the corresponding difference between the observed data and expected background distributions, together with the signal distribution for a SM Higgs boson at $m_{H}=125$ GeV. The distribution from SM Higgs boson events in the $WW$ decay channel does not significantly contribute to this plot.
png pdf Figure 18a: Scan of the negative log-likelihood difference, $-2\Delta\ln\mathcal{L}$, as a function of $m_H$. For each point, all nuisance parameters are profiled. The background-only hypothesis includes the $pp\rightarrow H_{(125~GeV)}\rightarrow WW$ process for every value of $m_H$. The observation (solid line) is compared to the expectation (dashed line) for a SM Higgs boson with mass $m_H = 125$ GeV.
png pdf Figure 18b: Likelihood scan as a function of $\kappa_V$ and $\kappa_f$. For each point, all nuisance parameters are profiled. The $HWW$ contribution is treated as a signal process. The observation (black cross) is compared to the expectation (red lozenge) for a SM Higgs boson with mass $m_H = 125$ GeV.

Additional Mass / Final Discriminant Distributions

Mass / Final Discriminant Distributions at 7 TeV

png pdf Figure 19a: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 0 jet, medium $p_T^{\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 19b: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 0 jet, high $p_T^{\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 19c: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 1 jet, medium $p_T^{\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 19d: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 1 jet, high $p_T^{\tau}$, low $p_T^{\tau\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 19e: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 1 jet, high $p_T^{\tau}$, medium $p_T^{\tau\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 19f: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the VBF category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 21a: Observed and predicted $m_{\tau\tau}$ distributions in the $e\tau_h$ channel, for the 0 jet, medium $p_T^{\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 21b: Observed and predicted $m_{\tau\tau}$ distributions in the $e\tau_h$ channel, for the 0 jet, high $p_T^{\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 21c: Observed and predicted $m_{\tau\tau}$ distributions in the $e\tau_h$ channel, for the 1 jet, medium $p_T^{\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 21d: Observed and predicted $m_{\tau\tau}$ distributions in the $e\tau_h$ channel, for the 1 jet, high $p_T^{\tau}$, medium $p_T^{\tau\tau}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 21e: Observed and predicted $m_{\tau\tau}$ distributions in the $e\tau_h$ channel, for the VBF category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 23a: Observed and predicted $m_{\tau\tau}$ distributions in the $e\mu$ channel, for the 0 jet, low $p_T^{\mu}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 23b: Observed and predicted $m_{\tau\tau}$ distributions in the $e\mu$ channel, for the 0 jet, high $p_T^{\mu}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 23c: Observed and predicted $m_{\tau\tau}$ distributions in the $e\mu$ channel, for the 1 jet, low $p_T^{\mu}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 23d: Observed and predicted $m_{\tau\tau}$ distributions in the $e\mu$ channel, for the 1 jet, high $p_T^{\mu}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 23e: Observed and predicted $m_{\tau\tau}$ distributions in the $e\mu$ channel, for the VBF used in the 7 TeV category data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 25a: Observed and predicted D distributions in the $\mu\mu$ channel, for the 0 jet, low $p_T^{\mu}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 25b: Observed and predicted D distributions in the $\mu\mu$ channel, for the 0 jet, high $p_T^{\mu}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 25c: Observed and predicted D distributions in the $\mu\mu$ channel, for the 1 jet, low $p_T^{\mu}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 25d: Observed and predicted D distributions in the $\mu\mu$ channel, for the 1 jet, high $p_T^{\mu}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 25e: Observed and predicted D distributions in the $\mu\mu$ channel, for the 2 jets category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.

png pdf Figure 27a: Observed and predicted D distributions in the $ee$ channel, for the 0 jet, low $p_T^{e}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 27b: Observed and predicted D distributions in the $ee$ channel, for the 0 jet, high $p_T^{e}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 27c: Observed and predicted D distributions in the $ee$ channel, for the 1 jet, low $p_T^{e}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 27d: Observed and predicted D distributions in the $ee$ channel, for the 1 jet, high $p_T^{e}$ category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 27e: Observed and predicted D distributions in the $ee$ channel, for the 2 jets category used in the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.

png pdf Figure 29a: Observed and predicted $m_{vis}$ distributions in the $\mu+\mu\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 29b: Observed and predicted $m_{vis}$ distributions in the $e+\mu\tau_h / \mu+e\tau_h $ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 30a: Observed and predicted $m_{vis}$ distributions in the $\mu+\tau_h\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 30b: Observed and predicted $m_{vis}$ distributions in the $e+\tau_h\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 31a: Observed and predicted $m_{\tau\tau}$ distributions for the $\mu\mu+\mu\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 31b: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+\mu\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 31c: Observed and predicted $m_{\tau\tau}$ distributions for the $\mu\mu+e\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 31d: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+e\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 31e: Observed and predicted $m_{\tau\tau}$ distributions for the $\mu\mu+\tau_h\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 31f: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+\tau_h\tau_h$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 31g: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+e\mu$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 31h: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+e\mu$ channel for the 7 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

Mass / Final Discriminant Distributions at 8 TeV

png pdf Figure 20a: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 0 jet, medium $p_T^{\tau}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 20b: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 0 jet, high $p_T^{\tau}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 20c: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 1 jet, medium $p_T^{\tau}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 20d: Observed and predicted $m_{\tau\tau}$ distributions in the $\mu\tau_h$ channel, for the 1 jet, high $p_T^{\tau}$, low $p_T^{\tau\tau}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 22a: Observed and predicted $m_{\tau\tau}$ distributions in the $e\tau_h$ channel, for the 0 jet, medium $p_T^{\tau}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 22b: Observed and predicted $m_{\tau\tau}$ distributions in the $e\tau_h$ channel, for the 0 jet, high $p_T^{\tau}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 22c: Observed and predicted $m_{\tau\tau}$ distributions in the $e\tau_h$ channel, for the 1 jet, medium $p_T^{\tau}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 24a: Observed and predicted $m_{\tau\tau}$ distributions in the $e\mu$ channel, for the 0 jet, low $p_T^{\mu}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 24b: Observed and predicted $m_{\tau\tau}$ distributions in the $e\mu$ channel, for the 0 jet, high $p_T^{\mu}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 24c: Observed and predicted $m_{\tau\tau}$ distributions in the $e\mu$ channel, for the 1 jet, low $p_T^{\mu}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 26a: Observed and predicted D distributions in the $\mu\mu$ channel, for the 0 jet, low $p_T^{\mu}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 26b: Observed and predicted D distributions in the $\mu\mu$ channel, for the 1 jet, low $p_T^{\mu}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.

png pdf Figure 28a: Observed and predicted D distributions in the $ee$ channel, for the 0 jet, low $p_T^{e}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.
png pdf Figure 28b: Observed and predicted D distributions in the $ee$ channel, for the 1 jet, low $p_T^{e}$ category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The open signal histogram is shown superimposed to the background histograms, which are stacked.

png pdf Figure 29c: Observed and predicted $m_{vis}$ distributions in the $\mu+\mu\tau_h$ channels for the low-LT category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 29d: Observed and predicted $m_{vis}$ distributions in the $e+\mu\tau_h / \mu+e\tau_h$ channels for the low-LT category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 29e: Observed and predicted $m_{vis}$ distributions in the $\mu+\mu\tau_h$ channels for the high-LT category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 29f: Observed and predicted $m_{vis}$ distributions in the $e+\mu\tau_h / \mu+e\tau_h$ channels for the high-LT category used in the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 30c: Observed and predicted $m_{vis}$ distributions in the $\mu+\tau_h\tau_h$ channel for the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 30d: Observed and predicted $m_{vis}$ distributions in the $e+\tau_h\tau_h$ channel for the 8 TeV data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

png pdf Figure 32a: Observed and predicted $m_{\tau\tau}$ distributions for the $\mu\mu+\mu\tau_h$ channel for the 8 Tev data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 32b: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+\mu\tau_h$ channel for the 8 Tev data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 32c: Observed and predicted $m_{\tau\tau}$ distributions for the $\mu\mu+e\tau_h$ channel for the 8 Tev data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 32d: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+e\tau_h$ channel for the 8 Tev data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 32e: Observed and predicted $m_{\tau\tau}$ distributions for the $\mu\mu+\tau_h\tau_h$ channel for the 8 Tev data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 32f: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+\tau_h\tau_h$ channel for the 8 Tev data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 32g: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+e\mu$ channel for the 8 Tev data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.
png pdf Figure 32h: Observed and predicted $m_{\tau\tau}$ distributions for the $ee+e\mu$ channel for the 8 Tev data analysis. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction. The signal and background histograms are stacked.

Tables from CMS-HIG-13-004

png pdf Table 1: Lepton selection for the $LL'$ and $l+l\tau_h$ channels. The HLT requirement is defined by a combination of trigger objects with $p_T$ over a given threshold. The $p_T$ and $I^{\tau_h}$ thresholds are given in GeV. The indices 1 and 2 denote, respectively, the leptons with the highest and next-to- highest $p_T$. For a number of channels, the isolation requirements depend on the lepton flavour, $p_T$, and $\eta$. Similarly, a range of $p_T$ thresholds is given when the HLT requirements change with the data-taking period.
png pdf Table 2: Lepton selection for the $ll + LL'$ channels. The HLT requirement is defined by a combination of trigger objects over a $p_T$ threshold indicated in GeV. The $p_T$ and $I^{\tau_h}$ thresholds are given in GeV. The indices 1 and 2 denote, respectively, the leptons with the highest and next-to-highest $p_T$.
png pdf Table 3: Systematic uncertainties, affected samples, and change in acceptance resulting from a variation of the nuisance parameter equivalent to one standard deviation. Several systematic uncertainties are treated as (partially) correlated for different decay channels and/or categories.
png pdf Table 4: Observed and predicted event yields in all event categories of the $\mu\tau_h$, $e\tau_h$, $\tau_h\tau_h$ and $e\mu$ channels in the full $m_{\tau\tau}$ mass range. The event yields of the predicted background distributions correspond to the result of the global fit. The signal yields, on the other hand, are normalized to the standard model prediction. The different signal processes are labelled as ggH (gluon-gluon fusion), VH (production in association with a $W$ or $Z$ boson), and VBF (vector-boson fusion). The S variable denotes the ratio of the signal and the signal-plus-background yields in the S+B central $m_{\tau\tau}$ range containing 68% of the signal events for $m_H = 125$ GeV. The RMS variable denotes the standard deviation of the $m_{\tau\tau}$ distribution for corresponding signal events.
png pdf Table 5: Observed and predicted event yields in all event categories of the $\mu\mu$ and $ee$ channel for the full discriminator value D region. The event yields of the predicted background distributions correspond to the result of the global fit. The signal yields, on the other hand, are normalized to the standard model prediction. The different signal processes are labelled as ggH (gluon-gluon fusion), VH (production in association with a $W$ or $Z$ boson), and VBF (vector-boson fusion).
png pdf Table 6: Observed and predicted event yields in all event categories of the $ll + LL'$ and $l + L\tau_h$ channels for the full $m_{\tau\tau}$ and $m_{vis}$ regions, respectively. The event yields of the predicted background distributions correspond to the result of the global fit. The signal yields, on the otherhand, are normalized to the standard model prediction. Only SM Higgs boson production ($m_H = 125$ GeV) in association with a $W$ or $Z$ boson is considered as a signal process. The S/S+B variable denotes the ratio of the signal and the signal-plus-background yields in the central $m_{\tau\tau}$ range containing 68% of the signal events for $m_H = 125$ GeV.

Additional Material (not in the Paper)

Results

png pdf Figure TWiki 1a: Expected 95% CL upper limit on the signal strength parameter $\mu = \sigma/\sigma_{SM}$ in the background only hypothesis, shown separately for the seven channels.
png pdf Figure TWiki 1b: Expected 95% CL upper limit on the signal strength parameter $\mu = \sigma/\sigma_{SM}$ in the background only hypothesis, shown separately for 0-Jet, 1-Jet, VBF, VH categories.
png pdf Figure TWiki 1c: Expected 95% CL upper limit on the signal strength parameter $\mu = \sigma/\sigma_{SM}$ in the background only hypothesis, shown separately for each $VH$ channel.
png pdf Figure TWiki 2a: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $ee$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 2b: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $\mu\mu$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 2c: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $e\mu$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 2d: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $\tau_h\tau_h$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 2e: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $e\tau_h$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 2f: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $\mu\tau_h$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 2g: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $ll'+LL'$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 2h: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $l+l'\tau_h$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 2i: Observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV in the $l+\tau_h\tau_h$ channel. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 3: Combined $VH$ observed 95% CL upper limit on the signal strength parameter $\mu=\sigma/\sigma_{SM}$, together with the expected limit obtained in the background-only hypothesis for a SM Higgs boson with $m_{\rm H}=125$ GeV. The background-only hypothesis includes the $pp \rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 4: Combined observed 95% CL upper limit on the signal strength parameter $\mu = \sigma/\sigma_{SM}$, together with the expected limit obtained in the background only hypothesis, where the SM Higgs boson with $m_H$ = 125 GeV is included as part of the background. The bands show the expected one- and two-standard-deviation probability intervals around the expected limit.
png pdf Figure TWiki 5: Combined observed and predicted distributions of the decimal logarithm $\log(S/(S+B))$ in each bin of the final $m_{\tau\tau}$, $m_{vis}$, or discriminator distributions obtained in all event categories and decay channels, with $S/(S+B)$ denoting the ratio of the predicted signal and signal-plus-background event yields in each bin. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution, on the other hand, is normalized to the SM prediction ($\mu=1$). The inset shows the corresponding difference between the observed data and expected background distributions, together with the signal distribution for a SM Higgs boson at $m_H=125$ GeV. The distribution from SM Higgs boson events in the $WW$ decay channel does not significantly contribute to this plot.
png pdf Figure TWiki 6: Best-fit signal strength values, for independent categories from different channels, with $m_H$ = 125 GeV. The combined value for the $H\rightarrow\tau\tau$ analysis in both plots corresponds to $\hat{\mu}$ = 0.78 0.27, obtained in the global fit combining all categories of all channels. This plot assesses the compatibility of $\mu$ values as measured in different channels/categories. All categories in all channels are simultaneously fit so that inter-category correlations for background constraints are preserved. The signal strength is measured separately in each category of each channel.
png pdf Figure TWiki 7: Likelihood scan as a function of $m_H$ and $\mu$. For each point, all nuisance parameters are profiled. The $HWW$ contribution is treated as a background process.
png pdf Figure TWiki 8: Likelihood scan as a function of the Higgs coupling to vector bosons, $mu_{qqH,VH}$, and to fermions, $\mu_{ggH,ttH}$. For each point, all nuisance parameters are profiled. The $HWW$ contribution is treated as a signal process.
png pdf Figure TWiki 9: Local $p$-value and significance in number of standard deviations as a function of the SM Higgs boson mass hypothesis for the combination of all decay channels. The observation (solid line) is compared to the uncertainty bands on the expectation for a SM Higgs boson with $m_H=125$ GeV. The background-only hypothesis includes the $pp\rightarrow H_{(125~GeV)}\rightarrow WW $ process for every value of $m_H$.

Table TWiki 1: Combined observed 95% CL upper limit on the signal strength parameter $\mu = \sigma/\sigma_{SM}$, together with the expected limit obtained in the background hypothesis and the one- and two standard- deviation probability intervals around the expected limit. This result corresponds to Fig. 25a and includes the search for a SM Higgs boson decaying into $\tau_h\tau_h$.

SM Higgs Expected Limit - Background Only
$m_H$ $-2\sigma$ $-1\sigma$ Median $+1\sigma$ $+2\sigma$ Obs. Limit [pb]
90 0.430 0.578 0.812 1.15 1.58 0.534
95 0.449 0.600 0.848 1.20 1.65 0.785
100 0.436 0.586 0.824 1.18 1.61 1.12
105 0.375 0.505 0.713 1.02 1.40 1.16
110 0.311 0.421 0.596 0.859 1.19 1.24
115 0.290 0.393 0.557 0.798 1.10 1.28
120 0.279 0.377 0.533 0.765 1.06 1.27
125 0.276 0.372 0.525 0.754 1.04 1.26
130 0.294 0.398 0.564 0.805 1.11 1.34
135 0.346 0.467 0.658 0.944 1.30 1.38
140 0.417 0.559 0.793 1.13 1.56 1.39
145 0.548 0.739 1.04 1.49 2.05 1.62

Table TWiki 2: Local $p$-value and significance in number of standard deviations as a function of the SM Higgs boson mass hypothesis for the combination of all decay channels.

SM Higgs Significance p-value
$m_H$ Expected Observed Expected Observed
90 2.4 0 0.00825 -
95 2.32 0 0.0101 -
100 2.41 1.02 0.00796 0.152
105 2.86 1.79 0.00212 0.0361
110 3.37 2.78 0.000377 0.00269
115 3.58 3.16 0.00017 0.000777
120 3.72 3.32 0.0001 0.00045
125 3.73 3.20 0.0000946 0.000681
130 3.52 3.10 0.000217 0.000974
135 3.01 2.52 0.00132 0.00591
140 2.53 1.78 0.00572 0.0376
145 1.92 1.32 0.0272 0.0931

Table TWiki 3: Each row in the table reports the ($\mu_{qqH,VH}$, $\mu_{ggH,ttH}$) coordinates of each point, for which the likelihood scan is performed, defining the 68% and 95% CL contours, as shown in Fig. Twiki 8. Signal is assumed to be at $m_H$ = 125 GeV and $H\rightarrow WW$ contribution is considered as part of the signal.

68% CL contour 95% CL contour
$mu_{qqH,VH}$ $\mu_{ggH,ttH}$ $mu_{qqH,VH}$ $\mu_{ggH,ttH}$
1.37500e+00 9.48544e-01 1.47500e+00 1.09191e+00
1.36691e+00 9.50000e-01 1.42500e+00 1.10972e+00
1.32500e+00 9.56774e-01 1.39870e+00 1.11667e+00
1.27500e+00 9.57394e-01 1.37500e+00 1.12260e+00
1.22500e+00 9.50380e-01 1.32500e+00 1.13086e+00
1.22369e+00 9.50000e-01 1.27500e+00 1.13492e+00
1.17500e+00 9.33477e-01 1.22500e+00 1.13465e+00
1.14296e+00 9.16667e-01 1.17500e+00 1.12991e+00
1.12500e+00 9.05424e-01 1.12500e+00 1.12050e+00
1.09859e+00 8.83333e-01 1.11128e+00 1.11667e+00
1.07500e+00 8.59189e-01 1.07500e+00 1.10533e+00
1.06775e+00 8.50000e-01 1.02500e+00 1.08420e+00
1.04649e+00 8.16667e-01 1.02334e+00 1.08333e+00
1.03009e+00 7.83333e-01 9.75000e-01 1.05455e+00
1.02500e+00 7.69424e-01 9.68617e-01 1.05000e+00
1.01893e+00 7.50000e-01 9.28023e-01 1.01667e+00
1.01181e+00 7.16667e-01 9.25000e-01 1.01378e+00
1.00779e+00 6.83333e-01 8.97243e-01 9.83333e-01
1.00675e+00 6.50000e-01 8.75000e-01 9.54165e-01
1.00870e+00 6.16667e-01 8.72167e-01 9.50000e-01
1.01379e+00 5.83333e-01 8.53050e-01 9.16667e-01
1.02242e+00 5.50000e-01 8.37534e-01 8.83333e-01
1.02500e+00 5.43107e-01 8.25207e-01 8.50000e-01
1.03747e+00 5.16667e-01 8.25000e-01 8.49288e-01
1.05986e+00 4.83333e-01 8.16301e-01 8.16667e-01
1.07500e+00 4.66728e-01 8.09700e-01 7.83333e-01
1.09759e+00 4.50000e-01 8.05091e-01 7.50000e-01
1.12500e+00 4.34721e-01 8.02201e-01 7.16667e-01
1.17500e+00 4.20829e-01 8.00807e-01 6.83333e-01
1.22500e+00 4.18735e-01 8.00748e-01 6.50000e-01
1.27500e+00 4.25843e-01 8.01910e-01 6.16667e-01
1.32500e+00 4.40302e-01 8.04200e-01 5.83333e-01
1.34779e+00 4.50000e-01 8.07592e-01 5.50000e-01
1.37500e+00 4.62263e-01 8.12170e-01 5.16667e-01
1.41088e+00 4.83333e-01 8.18072e-01 4.83333e-01
1.42500e+00 4.92269e-01 8.25000e-01 4.52320e-01
1.45600e+00 5.16667e-01 8.25581e-01 4.50000e-01
1.47500e+00 5.33117e-01 8.35974e-01 4.16667e-01
1.49119e+00 5.50000e-01 8.49270e-01 3.83333e-01
1.51926e+00 5.83333e-01 8.66298e-01 3.50000e-01
1.52500e+00 5.91563e-01 8.75000e-01 3.36197e-01
1.53974e+00 6.16667e-01 8.90277e-01 3.16667e-01
1.55492e+00 6.50000e-01 9.23191e-01 2.83333e-01
1.56529e+00 6.83333e-01 9.25000e-01 2.81775e-01
1.57029e+00 7.16667e-01 9.75000e-01 2.50431e-01
1.56949e+00 7.50000e-01 9.76044e-01 2.50000e-01
1.56254e+00 7.83333e-01 1.02500e+00 2.32016e-01
1.54929e+00 8.16667e-01 1.07500e+00 2.22773e-01
1.52972e+00 8.50000e-01 1.12500e+00 2.21031e-01
1.52500e+00 8.56160e-01 1.17500e+00 2.25647e-01
1.49822e+00 8.83333e-01 1.22500e+00 2.35823e-01
1.47500e+00 9.02651e-01 1.27158e+00 2.50000e-01
1.45208e+00 9.16667e-01 1.27500e+00 2.50985e-01
1.42500e+00 9.30944e-01 1.32500e+00 2.70480e-01
1.37500e+00 9.48544e-01 1.35179e+00 2.83333e-01
1.37500e+00 2.94135e-01
1.41569e+00 3.16667e-01
1.42500e+00 3.21766e-01
1.46928e+00 3.50000e-01
1.47500e+00 3.53667e-01
1.51540e+00 3.83333e-01
1.52500e+00 3.90541e-01
1.55580e+00 4.16667e-01
1.57500e+00 4.33568e-01
1.59169e+00 4.50000e-01
1.62382e+00 4.83333e-01
1.62500e+00 4.84664e-01
1.65043e+00 5.16667e-01
1.67475e+00 5.50000e-01
1.67500e+00 5.50398e-01
1.69384e+00 5.83333e-01
1.71018e+00 6.16667e-01
1.72346e+00 6.50000e-01
1.72500e+00 6.55264e-01
1.73241e+00 6.83333e-01
1.73796e+00 7.16667e-01
1.74009e+00 7.50000e-01
1.73868e+00 7.83333e-01
1.73364e+00 8.16667e-01
1.72500e+00 8.49790e-01
1.72494e+00 8.50000e-01
1.71086e+00 8.83333e-01
1.69271e+00 9.16667e-01
1.67500e+00 9.43425e-01
1.66995e+00 9.50000e-01
1.64013e+00 9.83333e-01
1.62500e+00 9.98259e-01
1.60311e+00 1.01667e+00
1.57500e+00 1.03806e+00
1.55628e+00 1.05000e+00
1.52500e+00 1.06839e+00
1.49402e+00 1.08333e+00
1.47500e+00 1.09191e+00

Event Display

$\mu\tau_h$ VBF

png Figure TWiki 10: 3D view of a candidate HTauTau VBF event in the $\mu\tau_h$ channel, recorded by CMS during 2012. The muon, represented by the red line on the left with hits visible in the endcap muon chambers, has a $p_T$ of 23.4 GeV. The hadronically-decaying $\tau$ candidate, indicated by the two large blue towers in the center of this figure, has a $p_T$ of 39.3 GeV. The di-tau mass, calculated using the svfit algorithm, is 102.0 GeV. The two jets passing the VBF selection, indicated by the large green towers in the two opposite-side endcaps, have $p_T$ 77.6 and 75.4 GeV, are separated in eta by 5.8 and have a mass of 1.4 TeV. There are no additional jets in the eta range between these tagging jets with a $p_T$ above 30 GeV.

$e\tau_h$ VBF

png Figure TWiki 11: 3D view of a candidate HTauTau VBF event in the $e\tau_h$ channel, recorded by CMS during 2012. The muon, represented by the yellow cone pointing downwards with large deposits (green towers) in ECal barrel, has a $p_T$ of 32.3 GeV. The hadronically-decaying $\tau$ candidate, indicated by the yellow cone pointing upwards in the center of this figure, has a $p_T$ of 70.9 GeV. The di-tau mass, calculated using the svfit algorithm, is 114.2 GeV. The two jets passing the VBF selection, indicated by the two yellow cones, containing calorimetic deposits in the opposite-side endcaps, have $p_T$ 63.7 and 49.8 GeV, are separated in eta by 6.1 and have a mass of 1.2 TeV. There are no additional jets in the eta range between these tagging jets with a $p_T$ above 30 GeV.

$\mu\tau_h$ 1 jet, medium Higgs boost

png Figure TWiki 12: 3D view of a candidate HTauTau with large transverse momentum event in the $\mu\tau_h$ channel, recorded by CMS during 2012. The muon, represented by the red line pointing downwards with hits visible in the barrel muon chambers, has a $p_T$ of 59.8 GeV. The hadronically-decaying $\tau$ candidate, indicated by the yellow cone on the left, containing large deposits in ECal, has a $p_T$ of 46.3 GeV. The di-tau mass, calculated using the svfit algorithm, is 119.2 GeV. An additional jet, indicated by the yellow cone in the upper half of the figure, has $p_T$ of 126.8 GeV and recoils against the $\mu\tau_h$ system which has a transverse momentum $p_T^{\tau\tau}$ of 117.7 GeV.

$e\tau_h$ 1 jet, medium Higgs boost

png Figure TWiki 13: 3D view of a candidate HTauTau with large transverse momentum event in the $e\tau_h$ channel, recorded by CMS during 2012. The electron, represented by yellow cone pointing downwards with hits visible in the barrel sections of the calorimeters, has a $p_T$ of 29.2 GeV. The hadronically-decaying $\tau$ candidate, indicated by the yellow cone pointing leftwards in the figure, has a $p_T$ of 55.8 GeV. The di-tau mass, calculated using the svfit algorithm, is 126.7!GeV. An additional jet, indicated by the yellow cone pointing upwards, has $p_T$ of 124.4 GeV and recoils against the $\mu\tau_h$ system which has a transverse momentum $p_T^{\tau\tau}$ of 144.4 GeV.

$ZH\rightarrow\mu\mu~\mu\tau_h$

png Figure TWiki 14: 3D view of a candidate HTauTau event produced in association with a $Z$ boson, recorded by CMS during 2012. The HTauTau candidate decays in the $\mu\tau_h$ channel and the $Z$ boson candidate decays into the di-$\mu$ channel. In the figure, starting from the upper left corner and proceeding clockwise, the yellow cone indicates the hadronic-decaying tau ($p_T$ 19.0 GeV) coming from the Higgs boson, the first red line in the negative pseudorapidity region represents the first muon ($p_T$ 18.4 GeV), daughter of the $Z$ boson, then, in the positive pseudorapidity, region the second red line indicates the muon ($p_T$ 47.5 GeV) coming from the Higgs boson and the third red line represents the second muon coming from the $Z$ boson ($p_T$ 22.0 GeV). The $Z$ boson candidate has mass 91.0 GeV and the di-tau mass of the Higgs boson candidate, calculated using the svfit algorithm, is 122.8 GeV.

$\mu\tau_h$ control plots

png pdf Figure TWiki 15: Observed and predicted distributions of the transverse momentum of the muon, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 16: Observed and predicted distributions of the transverse momentum of the tau, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 17: Observed and predicted distributions of the pseudorapidity of the muon, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 18: Observed and predicted distributions of the pseudorapidity of the tau, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 19: Observed and predicted distributions of the transverse momentum of the Higgs boson candidates, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 20: Observed and predicted distributions of the missing transverse energy, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 21: Observed and predicted distributions of the number of jets with transverse momentum larger than 30 GeV present in the event, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 22: Observed and predicted distributions of the invariant mass of the two jets with highest transverse momentum, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 23: Observed and predicted distributions of the pseudorapidity separation between the two jets with highest transverse momentum, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 24: Observed and predicted distributions of the decay mode of the tau, in the $\mu\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.

$e\tau_h$ control plots

png pdf Figure TWiki 25: Observed and predicted distributions of the transverse momentum of the electron, in the $e\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 26: Observed and predicted distributions of the transverse momentum of the tau, in the $e\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 27: Observed and predicted distributions of the pseudorapidity of the electron, in the $e\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 28: Observed and predicted distributions of the pseudorapidity of the tau, in the $e\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 29: Observed and predicted distributions of the transverse momentum of the Higgs boson candidates, in the $e\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 30: Observed and predicted distributions of the missing transverse energy, in the $e\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 31: Observed and predicted distributions of the number of jets with transverse momentum larger than 30 GeV present in the event, in the $e\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 32: Observed and predicted distributions of the invariant mass of the two jets with highest transverse momentum, in the $e\tau_h$ channel after the baseline selection and the request of at least two jets with transverse momentum larger than 30 GeV. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible
png pdf Figure TWiki 33: Observed and predicted distributions of the pseudorapidity separation between the two jets with highest transverse momentum, in the $e\tau_h$ channel after the baseline selection and the request of at least two jets with transverse momentum larger than 30 GeV. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 34: Observed and predicted distributions of the decay mode of the tau, in the $e\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.

$\tau_h\tau_h$ control plots

png pdf Figure TWiki 35: Observed and predicted distributions of the transverse momentum of the leading tau, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 36: Observed and predicted distributions of the transverse momentum of the sub-leading tau, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 37: Observed and predicted distributions of the pseudorapidity of the leading tau, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 38: Observed and predicted distributions of the pseudorapidity of the sub-leading tau, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 39: Observed and predicted distributions of the transverse momentum of the Higgs boson candidates, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 40: Observed and predicted distributions of the missing transverse energy, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 41: Observed and predicted distributions of the number of jets with transverse momentum larger than 30 GeV present in the event, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 42: Observed and predicted distributions of the invariant mass of the two jets with highest transverse momentum, in the $\tau_h\tau_h$ channel after the baseline selection and the request of at least two jets with transverse momentum larger than 30 GeV. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 43: Observed and predicted distributions of the pseudorapidity separation between the two jets with highest transverse momentum, in the $\tau_h\tau_h$ channel after the baseline selection and the request of at least two jets with transverse momentum larger than 30 GeV. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 44: Observed and predicted distributions of the decay mode of the leading tau, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 45: Observed and predicted distributions of the decay mode of the sub-leading tau, in the $\tau_h\tau_h$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.

$e\mu$ control plots

png pdf Figure TWiki 46: Observed and predicted distributions of the transverse momentum of the electron, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 47: Observed and predicted distributions of the transverse momentum of the muon, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 48: Observed and predicted distributions of the pseudorapidity of the electron, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 49: Observed and predicted distributions of the pseudorapidity of the muon, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 50: Observed and predicted distributions of the transverse momentum of the Higgs boson candidates, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 51: Observed and predicted distributions of the missing transverse energy, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 52: Observed and predicted distributions of the number of jets with transverse momentum larger than 30 GeV present in the event, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 53: Observed and predicted distributions of the invariant mass of the two jets with highest transverse momentum, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The bottom inset shows the ratio of the observed and predicted numbers of events. The expected contribution from the SM Higgs signal is negligible.
png pdf Figure TWiki 54: Observed and predicted distributions of the pseudorapidity separation between the two jets with highest transverse momentum, in the $e\mu$ channel after the baseline selection. The yields predicted for the various background contributions correspond to the result of the final fit, whereas shape variations are not taken into account. The electroweak background contribution includes events from $W+jets$, diboson, and single-top-quark production. The "bkg. uncertainty'' band represents the combined statistical and systematic uncertainty in the background yield in each bin. The expected contribution from the SM Higgs signal is negligible.

$\mu\mu$ control plots and BDT inputs

png pdf Figure TWiki 55: Expected and observed di-muon mass distributions in the $\mu\mu$ channel, and in the VBF category, which is used as input for the BDT 1.
png pdf Figure TWiki 56: Expected and observed SVFit mass distributions in the $\mu\mu$ channel, and in the VBF category, which is used as input for the BDT 2.
png pdf Figure TWiki 57: Expected and observed missing transverse energy distributions in the $\mu\mu$ channel, and in the VBF category, which is used as input for both BDTs.
png pdf Figure TWiki 58: Expected and observed di-jet mass distributions in the $\mu\mu$ channel, and in the VBF category, which is used as input for both BDTs.
png pdf Figure TWiki 59: Expected and observed distributions of the distance of closest approach (DCA) of the two muons in the $\mu\mu$ channel, and in the VBF category, which is used as input for both BDTs.
png pdf Figure TWiki 60: Expected and observed di-muon BDT 1 distributions in the $\mu\mu$ channel, and in the VBF category. This BDT was trained to discriminate between ditau final states and all other backgrounds.
png pdf Figure TWiki 61: Expected and observed SVfit BDT 2 distributions in the $\mu\mu$ channel, and in the VBF category. This BDT was trained to discriminate between $H\rightarrow\tau\tau$ and $Z\rightarrow\tau\tau$ events.

$ee$ control plots and BDT inputs

png pdf Figure TWiki 62: Expected and observed dielectron mass distributions in the $ee$ channel, and in the VBF category, which is used as input for the BDT 1.
png pdf Figure TWiki 63: Expected and observed SVFit mass distributions in the $ee$ channel, and in the VBF category, which is used as input for the BDT 2.
png pdf Figure TWiki 64: Expected and observed dijet mass distributions in the $ee$ channel, and in the VBF category, which is used as input for both BDTs.
png pdf Figure TWiki 65: Expected and observed di-electron BDT 1 distributions in the $ee$ channel, and in the VBF category. This BDT was trained to discriminate between ditau final states and all other backgrounds.
png pdf Figure TWiki 66: Expected and observed SVfit BDT 2 distributions in the $ee$ channel, and in the VBF category. This BDT was trained to discriminate between $H\rightarrow\tau\tau$ and $Z\rightarrow\tau\tau$ events.

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