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The Matrix Element Method: Past, Present, and Future

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arxiv 1307.3546 v2 pith:E25THZ67 submitted 2013-07-12 hep-ph hep-ex

The Matrix Element Method: Past, Present, and Future

classification hep-ph hep-ex
keywords willelementfuturematrixmethodmultivariatesomesophisticated
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The increasing use of multivariate methods, and in particular the Matrix Element Method (MEM), represents a revolution in experimental particle physics. With continued exponential growth in computing capabilities, the use of sophisticated multivariate methods-- already common-- will soon become ubiquitous and ultimately almost compulsory. While the existence of sophisticated algorithms for disentangling signal and background might naively suggest a diminished role for theorists, the use of the MEM, with its inherent connection to the calculation of differential cross sections will benefit from collaboration between theorists and experimentalists. In this white paper, we will briefly describe the MEM and some of its recent uses, note some current issues and potential resolutions, and speculate about exciting future opportunities.

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  1. Matrix element method at NLO: A fine proof of concept in POWHEG

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    Proof-of-concept for NLO matrix element method via POWHEG projections applied to fully leptonic WW production in SMEFT, demonstrating near-optimal classification of BSM versus SM events using lepton correlations.