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Constraining the anomalous Higgs boson coupling in ${\bf H+\gamma} $ production

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Liaoshan Shi, Zhijun Liang, Bo Liu and Zhenhui He. Constraining anomalous Higgs boson coupling in H+ $ \gamma $ production[J]. Chinese Physics C. doi: 10.1088/1674-1137/43/4/043001
Liaoshan Shi, Zhijun Liang, Bo Liu and Zhenhui He. Constraining anomalous Higgs boson coupling in H+ $ \gamma $ production[J]. Chinese Physics C.  doi: 10.1088/1674-1137/43/4/043001 shu
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Received: 2018-11-07
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Constraining the anomalous Higgs boson coupling in ${\bf H+\gamma} $ production

    Corresponding author: Liaoshan Shi, Liaoshan.Shi@cern.ch
  • 1. School of Physics, Sun Yat-sen University, Guangzhou 510275, China
  • 2. Institute of High Energy Physics, Chinese Academy of Sciences, Beijing 100049, China
  • 3. Physical Science Laboratory, Huairou National Comprehensive Science Center, Beijing 101400, China

Abstract: Higgs boson production in association with a photon (H+$ \gamma $) offers a promising channel to test the Higgs boson to photon coupling at various energy scales. Its potential sensitivity to anomalous couplings of the Higgs boson has not been explored with the proton-proton collision data. In this paper, we reinterpret the latest ATLAS H+$ \gamma $ resonance search results within the Standard Model effective field theory (EFT) framework, using 36.1 fb−1 of proton-proton collision data recorded with the ATLAS detector at $ \sqrt{s}=13 $ TeV. Constraints on the Wilson coefficients of dimension-six EFT operators related to the Higgs boson to photon coupling are provided for the first time in the H+$ \gamma $ final state at the LHC.

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    1.   Introduction
    • After the discovery of the Higgs boson [1, 2], measurements of the Higgs boson couplings to the other fundamental particles became crucial tests of the nature of the Higgs boson. In the Standard Model (SM), coupling of the Higgs boson to photon is forbidden at the tree level, and is induced by heavy particle loops in, e.g., $ H \to \gamma \gamma $ and $ H \to Z\gamma $ processes. The Higgs-photon coupling has been extensively studied in the various Higgs boson decay channels including $ H \to \gamma \gamma $ and $ H \to ZZ^{*}/Z\gamma^{*}/\gamma^{*}\gamma^{*} \to 4\ell $ with the LHC data recorded by the ATLAS and CMS experiments [3-11].

      Apart from the Higgs boson decay channels involving photons, Higgs boson production in association with a photon can also be used to measure the Higgs-photon coupling. The ${H\mathrm{+}\gamma}$ production cross section is predicted to be very small in SM, but anomalous couplings introduced in models beyond SM (BSM) can have significant effects. The ${H\mathrm{+}\gamma}$ process was considered as a promising and clean channel at LEP [12, 13], and was used by the DELPHI collaboration to search for anomalous couplings of the Higgs boson to vector bosons [14]. At the LHC, potential sensitivity of the $ pp\to {H\mathrm{+}\gamma}$ process to anomalous Higgs-photon couplings was discussed in Ref. [15]. It is predicted that some Wilson coefficients of dimension-six operators related to Higgs-photon couplings can be probed down to 10−2 with 300 fb−1 of pp collision data at 14 TeV. There is no particular analysis measuring anomalous Higgs-photon couplings via this channel using the LHC data. The ATLAS and CMS collaborations have reported the results of heavy ${H\mathrm{+}\gamma}$ resonance searches in 13 TeV pp collision data [16, 17]. Apart from the resonance models, their results are also sensitive to non-resonant ${H\mathrm{+}\gamma}$ production and to the anomalous coupling between the Higgs boson and photon. However, these results have not been interpreted as limits on the anomalous Higgs-photon coupling.

      In this paper, the latest ${H\mathrm{+}\gamma}$ resonance search results from the ATLAS collaboration [16] are reinterpreted within the SM effective field theory (EFT) and are presented as constraints on the Wilson coefficients of dimension-six EFT operators. The study is based on a pp collision dataset of 36.1 fb−1 at $ \sqrt{s} = 13 $ TeV.

      This paper is organized as follows. Section 2 gives a short overview of the EFT framework and a brief description of the signal Monte Carlo generation for the reinterpretation. Section 3 describes the analysis strategy. Section 4 presents the constraints on the Wilson coefficients of dimension-six EFT operators that are obtained in the $ H+\gamma $ channel, and compares them with the existing results from other measurements. Our conclusions are summarized in Section 5.

    2.   The effective field theory
    • In the SM effective field theory approach, the effects of BSM interactions are parametrized using higher-dimension operators in addition to the SM Lagrangian. Leading contributions at collider energies are expected to originate from dimension-six operators. A general effective Lagrangian with dimension-six operators $ {\cal O}_i $ takes the form

      ${{\cal L}_{{\rm{eff}}}} = {{\cal L}_{{\rm{SM}}}} + \sum\limits_i {{{\bar c}_i}} {O_i}.$

      (1)

      with the Wilson coefficients $ \bar c_i $ describing the strengths of the BSM interactions.

      We focus on a set of dimension-six operators known as the strongly-interacting light Higgs (SILH) Lagrangian [18]. It is written as

      $\begin{split} {{{\cal L}}_{{\rm{SILH}}}} =& \displaystyle\frac{{{{\bar c}_H}}}{{2{v^2}}}{\partial ^\mu }[{\Phi ^{\dagger} }\Phi ]{\partial _\mu }[{\Phi ^{\dagger} }\Phi ] + \displaystyle\frac{{{{\bar c}_T}}}{{2{v^2}}}\left[{\Phi ^{\dagger} }{{\overleftrightarrow{D}}^\mu }\Phi \right]\left[{\Phi ^{\dagger} }{{\overleftrightarrow{D}}_\mu }\Phi \right] \\ & - \displaystyle\frac{{{{\bar c}_6}\lambda }}{{{v^2}}}{\left[{\Phi ^{\dagger} }\Phi \right]^3}- \left[\displaystyle\frac{{{{\bar c}_u}}}{{{v^2}}}{y_u}{\Phi ^{\dagger} }\Phi \;{\Phi ^{\dagger} } \cdot {{\bar Q}_L}{u_R} \right. \\ & \left.+ \displaystyle\frac{{{{\bar c}_d}}}{{{v^2}}}{y_d}{\Phi ^{\dagger} }\Phi \;\Phi {{\bar Q}_L}{d_R}+ \displaystyle\frac{{{{\bar c}_l}}}{{{v^2}}}{y_\ell }\;{\Phi ^{\dagger} }\Phi \;\Phi {{\bar L}_L}{e_R} + {\rm{h}}.{\rm{c}}.\right]\\ & +\!\! \displaystyle\frac{{ig\;{{\bar c}_W}}}{{m_W^2}}\left[{\Phi ^{\dagger} }{T_{2k}}{{\overleftrightarrow{D}}^\mu }\Phi \right]{D^\nu }W_{\mu \nu }^k\!\! +\!\! \frac{{ig'\;{{\bar c}_B}}}{{2m_W^2}}\left[{\Phi ^{\dagger} }{{\overleftrightarrow{D}}^\mu }\Phi \right]{\partial ^\nu }{B_{\mu \nu }}\\ & + \displaystyle\frac{{2ig\;{{\bar c}_{HW}}}}{{m_W^2}}[{D^\mu }{\Phi ^{\dagger} }{T_{2k}}{D^\nu }\Phi ]W_{\mu \nu }^k\\& + \displaystyle\frac{{ig'\;{{\bar c}_{HB}}}}{{m_W^2}}[{D^\mu }{\Phi ^{\dagger} }{D^\nu }\Phi ]{B_{\mu \nu }}+ \displaystyle\frac{{{{g'}^2}\;{{\bar c}_\gamma }}}{{m_W^2}}{\Phi ^{\dagger} }\Phi {B_{\mu \nu }}{B^{\mu \nu }} \\&+ \displaystyle\frac{{g_s^2\;{{\bar c}_g}}}{{m_W^2}}{\Phi ^{\dagger} }\Phi G_{\mu \nu }^aG_a^{\mu \nu }, \end{split}$

      (2)

      where $ W_{\mu \nu}^k $, $ B_{\mu \nu} $ and $ G_{\mu \nu}^a $ are the gauge field strength tensors, and $ \Phi $ is the Higgs doublet. Among all Wilson coefficients in the SILH Lagrangian, ${\bar c_{\gamma}}$, ${\bar c_{HW}}$ and ${\bar c_{HB}}$ are related to the anomalous Higgs-photon coupling through a direct $ HZ\gamma $ or $ H\gamma\gamma $ vertex. With the presence of these BSM vertices, additional tree level diagrams, in particular an s-channel diagram via a virtual photon or Z boson as the mediator, can contribute to the $ pp\to {H\mathrm{+}\gamma}$ process and lead to a large relative change in its production cross section. Therefore, the ${H\mathrm{+}\gamma}$ process is a sensitive probe for exploring the anomalous Higgs-photon coupling [15].

      A public implementation of the SILH Lagrangian is available in the general Higgs Effective Lagrangian (HEL) [19, 20]. The HEL model is implemented in FeynRules [21], comprising 39 dimension-six operators and their corresponding Wilson coefficients. Its Universal FeynRules Output [22] has been interfaced to the MadGraph5_aMC@NLO [23] event generator. In this work, the HEL model is used with all the other Wilson coefficients fixed to 0 except ${\bar c_{\gamma}}$, ${\bar c_{HW}}$ and ${\bar c_{HB}}$. The $ pp\to {H\mathrm{+}\gamma}$ production cross section is computed for different values of ${\bar c_{\gamma}}$, ${\bar c_{HW}}$ and ${\bar c_{HB}}$, using MadGraph5_aMC@NLO v2.6.2 with NNPDF2.3 [24] parton distribution functions. We then parametrize the signal cross section as a function of the Wilson coefficients that result from the computation. Figure 1 presents a two-dimensional parametrization of the signal cross section parametrized as a function of two of the three Wilson coefficients, with the third coefficient fixed to 0. Monte Carlo event samples are also generated with the same configurations.

      Figure 1.  (color online) Two-dimensional parametrization of the signal cross section of the ${H\mathrm{+}\gamma}$ process with different values of ${\bar c_{\gamma}}$, ${\bar c_{HW}}$ and ${\bar c_{HB}}$. Apart from the two parameters indicated in each plot, the third parameter is fixed to 0.

    3.   Analysis strategy
    • The ATLAS ${H\mathrm{+}\gamma}$ resonance search [16] is carried out to search for heavy resonances decaying to the SM Higgs boson and a photon, using the $ b\bar b $ decay of the Higgs boson. In its signal region, both the selected photon and the Higgs boson are highly boosted (with large momenta). The search is performed by looking for a bump in the smooth background of the ${H\mathrm{+}\gamma}$ invariant mass spectrum $ m_{H\gamma} $. As reported in the ATLAS paper, the mass spectrum observed is consistent with the background-only hypothesis and no evidence of new resonances is found.

      The highly boosted signature is of particular interest for probing the anomalous Higgs-photon coupling, as the BSM signal contribution may show longer tails extending up to the TeV scale in the $ {m_{H\gamma}}$ and photon ${p_{\rm{T}}}$ distributions, while the SM expectation drops more steeply [15]. Instead of performing a bump hunt on the $ m_{H\gamma} $ spectrum as in the original ATLAS paper, we perform a counting experiment with the published $ m_{H\gamma} $ spectrum to constrain the anomalous coupling of the Higgs boson. According to the ATLAS paper [16], 138 events were observed in the signal region $ 800\;{\mathrm{GeV}}<m_{H\gamma}<3.2\;{\mathrm{TeV}} $, consistent with the expected number of background events $ 138\pm12 $. We reinterpret the ATLAS data as follows.

      The expected number of events in the signal region can be expressed as s+b, where s and b are the expected number of signal and background events, respectively. To constrain the Wilson coefficients, we construct a likelihood function assuming that the number of observed events n follows a Poisson distribution with an expectation value s+b:

      ${\cal L} = {\rm{Pois}}(n|s + b) \times {\rm{Gaus}}({b_0}|b,{\sigma _b}).$

      (3)

      Here b is treated as a nuisance parameter. It is constrained by a Gaussian term with a mean value b0 and a standard deviation $ \sigma_b $. Both b0 and $ \sigma_b $ are obtained from the background fits in the ATLAS ${H\mathrm{+}\gamma}$ paper [16]. The expected number of signal events s depends on the Wilson coefficients $ \bar c_i $. It can be further expressed as:

      $s = {L_{{\rm{int}}}} \times \varepsilon \times \sigma ({\bar c_i}) \times Br,$

      (4)

      The integrated luminosity Lint of the ATLAS data sample is 36.1 fb−1. The SM $ H\rightarrow b\bar b $ branching ratio Br = 58% for the 125 GeV Higgs boson [25] is used. The signal efficiency $ \varepsilon $ accounts for the event loss due to detector effects, and to the reconstruction and selection efficiencies in the ATLAS analysis. It is determined by applying the efficiency table published in the ATLAS ${H\mathrm{+}\gamma}$ paper [16] to the simulated ${m_{H\gamma}}$ spectra in the signal Monte Carlo samples, and allows to evaluate the overall efficiency. The ${H\mathrm{+}\gamma}$ production cross section $ \sigma(\bar c_i) $ is computed in terms of the Wilson coefficients ${\bar c_{\gamma}}$, ${\bar c_{HW}}$ and ${\bar c_{HB}}$, as described in Section 2. The Wilson coefficients ${\bar c_{\gamma}}$, ${\bar c_{HW}}$ and ${\bar c_{HB}}$ are treated as the parameters of interest (POIs).

      Constraints on the Wilson coefficients are obtained by evaluating the profiled likelihood ratio assuming the asymptotic approximation [26]:

      $\lambda ({\bar c_i}) = \frac{{{\cal L}({{\bar c}_i},\hat{\hat b})}}{{{\cal L}(\hat{\bar{c_i}},\hat b)}}.$

      (5)

      Here, the numerator is the conditional maximum-likelihood function, where $ \hat{\hat b} $ is the value of the nuisance parameter b that maximizes the likelihood function for a given set of values of the Wilson coefficients $ \bar c_i $. The denominator is the unconditional maximum-likelihood function, where $ \hat{\bar{c_i}} $ and $ \hat b $ are the maximum-likelihood estimates of $ \bar c_i $ and b, respectively.

    4.   Results and discussion
    • A one-dimensional likelihood scan is performed to obtain constraints on each of the three Wilson coefficients in the EFT framework with the other two fixed to 0. The constraints on ${\bar c_{\gamma}}$, ${\bar c_{HW}}$ and ${\bar c_{HB}}$ are shown in Figure 2. The 68% and 95% confidence intervals are shown in Table 1.

      Parameter68% C.L.95% C.L.
      ${\bar c_{\gamma}}$[−0.061, 0.064][−0.087, 0.090]
      ${\bar c_{HW}}$[−0.167, 0.161][−0.236, 0.231]
      ${\bar c_{HB}}$[−0.162, 0.167][−0.230, 0.236]

      Table 1.  The 68% and 95% confidence intervals for the Wilson coefficients ${\bar c_{\gamma}}$, ${\bar c_{HW}}$ and ${\bar c_{HB}}$ in the EFT framework.

      Figure 2.  (color online) One-dimensional likelihood scan of the Wilson coefficients ${\bar c_{\gamma}}$ (left), ${\bar c_{HW}}$ (middle) and ${\bar c_{HB}}$ (right) in the EFT framework with all the other coefficients fixed to 0. The 95% (68%) confidence interval is indicated by the red (green) line. The constraints are obtained from the data in the mass range 800 GeV < ${m_{H\gamma}}$ < 3.2 TeV.

      Two-dimensional likelihood scans are also performed and the confidence regions are shown in Figure 3. Apart from the two Wilson coefficients indicated in the plot, the remaining one is fixed to 0 during the scan.

      Figure 3.  (color online) Two-dimensional likelihood scan of the Wilson coefficients in the EFT framework. Apart from the two parameters indicated in each plot, the third parameter is fixed to 0. The 95% (68%) confidence region is indicated by the red (green) contour. The constraints are obtained from the data in the mass range 800 GeV < ${m_{H\gamma}}$ < 3.2 TeV. The SM expectation at (0, 0) is also shown.

      We compare the ${H\mathrm{+}\gamma}$ channel results with those obtained in the combined $ H \to \gamma\gamma $ and $ H \to ZZ^{*} \to 4\ell $ channels based on the same pp dataset collected by the ATLAS experiment. The 68% C.L. intervals from the combined channels [6] are:

      $\begin{array}{l} {{\bar c}_\gamma } \in [ - 1.5 \times {10^{ - 4}},\;2.2 \times {10^{ - 4}}],\\ {{\bar c}_{HW}} \in [ - 0.080,\; - 0.024],\\ {{\bar c}_{HB}} \in [ - 0.051,\;0.103]. \end{array}$

      While the limit on ${\bar c_{\gamma}}$ is much more stringent, the limits on ${\bar c_{HW}}$ and ${\bar c_{HB}}$ are of the same order of magnitude as the ${H\mathrm{+}\gamma}$ channel results. These results demonstrate excellent sensitivity of the ${H\mathrm{+}\gamma}$ production process to some of the Wilson coefficients in the EFT framework. The combination of the ${H\mathrm{+}\gamma}$ channel with the other channels could further improve the sensitivity for the Higgs boson anomalous couplings.

      The limits can be further improved by considering the shape information from the differential distributions instead of doing a simple counting experiment. In the $ H\to\gamma\gamma $ channel, the 95% C.L. observed limit for ${\bar c_{HW}}$ has been improved to −0.057 < ${\bar c_{HW}}$ < 0.051 after including differential distributions [4], which is four times better than the limit achieved from the ${H\mathrm{+}\gamma}$ channel in our study. In the ${H\mathrm{+}\gamma}$ channel, improvements to the sensitivity are also anticipated by including additional information from the ${m_{H\gamma}}$ and photon ${p_{\rm{T}}}$ distributions, but we consider the shape analysis beyond the scope of this paper.

    5.   Conclusions
    • We present an interpretation of the recent ATLAS ${H\mathrm{+}\gamma}$ resonance search results with 36.1 fb−1 of pp collision data at $ \sqrt{s} = 13 $ TeV in view of the search for the Higgs boson anomalous coupling in the ${H\mathrm{+}\gamma}$ final state. We provide constraints on the Wilson coefficients of dimension-six EFT operators for the first time in the ${H\mathrm{+}\gamma}$ final state with pp collision data. These results demonstrate excellent physics potential of the ${H\mathrm{+}\gamma}$ production process. With differential cross sections measured for the ${H\mathrm{+}\gamma}$ process in the future, the constraints can be further improved.

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