Abstract
In this paper we propose to use convolutional neural networks (CNNs) to improve the precision measurement of the Higgs boson-gluon effective coupling at lepton colliders. The CNN is employed to recognize the Higgs boson and a $Z$ boson associated production process, with the Higgs boson decaying to a gluon pair and the $Z$ boson decaying to a lepton pair at the center-of-mass energy 250 GeV and integrated luminosity 5 ab$^{-1}$. By using CNNs, the uncertainty of the effective coupling measurement can be decreased from $1.94\%$ to about $1.28\%$ using the PYTHIA data and from $1.82\%$ to about $1.22\%$ using the HERWIG data in the Monte Carlo simulation. Moreover, the performance of CNNs using different final state constituents shows that the energy distributions of the leading and subleading jets constituents play a major role in the identification and the optimal uncertainty of effective coupling using CNNs is reduced by about $35\%$ compared to that using conventional method.
Highlights
The Higgs boson occupies a distinct place in the Standard Model (SM) of particle physics
The performance of convolutional neural networks (CNNs) using different final state constituents shows that the energy distributions of the leading and subleading jets constituents play a major role in the identification and the optimal uncertainty of effective coupling using CNNs is reduced by about 35% compared to that using conventional method
We propose to use the CNN for the precision measurement of Higgs boson-gluon effective coupling by distinguishing the background processes from the process of a Z boson decaying to a lepton pair and a Higgs boson decaying to a gluon pair (2l2g) at lepton colliders
Summary
The Higgs boson occupies a distinct place in the Standard Model (SM) of particle physics. Deep neural networks have been employed to distinguish different types of jets, including Higgs boson tagging [30], boosted W boson tagging [31,32], boosted top tagging [33,34], single merged jet tagging [35], heavy-light quark discrimination [36], and quark-gluon discrimination [37,38,39,40]. They all get an exciting recognition capability and superior to the conventional method.
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