Abstract
We study several simplified dark matter (DM) models and their signatures at the LHC using neural networks. We focus on the usual monojet plus missing transverse energy channel, but to train the algorithms we organize the data in 2D histograms instead of event-by-event arrays. This results in a large performance boost to distinguish between standard model (SM) only and SM plus new physics signals. We use the kinematic monojet features as input data which allow us to describe families of models with a single data sample. We found that the neural network performance does not depend on the simulated number of background events if they are presented as a function of S/\sqrt{B}S/B, for reasonably large BB, where SS and BB are the number of signal and background events per histogram, respectively. This provides flexibility to the method, since testing a particular model in that case only requires knowing the new physics monojet cross section. Furthermore, we also discuss the network performance under incorrect assumptions about the true DM nature. Finally, we propose multimodel classifiers to search and identify new signals in a more general way, for the next LHC run.
Highlights
The deep neural networks (DNN) results do not depend on the simulated number of standard model (SM) events within the explored range when we present the performance as a function of S/ B, where S and B are the number of signal and background events per histogram, respectively
In this work we have analyzed the performance of DNN to disentangle dark matter signatures from SM background at the Large Hadron Collider (LHC)
We saw that using the monojet kinematic features organized as 2D histograms improves significantly the DNN efficiency, but introduces extra parameters, namely the ratio between signal and background events, S and B, respectively
Summary
The standard model of particles (SM) provides a remarkably successful description of the elementary particle phenomena explored so far without precedent. To ease the blind DM identification and discrimination from the SM background, we explore multiclass classifiers, i.e. DNN trained with more than one DM scenario This approach shows good efficiencies, and even slightly outperforms some individually trained DNNs. Two methods are explored, a binary classifier prepared to distinguish SM-only histograms from samples with SM plus new physic events generated from several benchmark models, and a multiclass classifier to identify the most likely DM scenario among those considered. A binary classifier prepared to distinguish SM-only histograms from samples with SM plus new physic events generated from several benchmark models, and a multiclass classifier to identify the most likely DM scenario among those considered In the latter, crucial information about the kinematic distributions and hints of the true underlying model can be extracted.
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