Analytic boosted boson discrimination

Author(s)

Moult, Ian; Larkoski, Andrew J.; Neill, Duff Austin

Abstract

Observables which discriminate boosted topologies from massive QCD jets are of great importance for the success of the jet substructure program at the Large Hadron Collider. Such observables, while both widely and successfully used, have been studied almost exclusively with Monte Carlo simulations. In this paper we present the first all-orders factorization theorem for a two-prong discriminant based on a jet shape variable, D 2, valid for both signal and background jets. Our factorization theorem simultaneously describes the production of both collinear and soft subjets, and we introduce a novel zero-bin procedure to correctly describe the transition region between these limits. By proving an all orders factorization theorem, we enable a systematically improvable description, and allow for precision comparisons between data, Monte Carlo, and first principles QCD calculations for jet substructure observables. Using our factorization theorem, we present numerical results for the discrimination of a boosted Z boson from massive QCD background jets. We compare our results with Monte Carlo predictions which allows for a detailed understanding of the extent to which these generators accurately describe the formation of two-prong QCD jets, and informs their usage in substructure analyses. Our calculation also provides considerable insight into the discrimination power and calculability of jet substructure observables in general.

Date issued

2016-05

URI

http://hdl.handle.net/1721.1/103301

Department

Massachusetts Institute of Technology. Center for Theoretical Physics
Massachusetts Institute of Technology. Department of Physics

Journal

Journal of High Energy Physics

Publisher

Springer Berlin Heidelberg

Citation

Larkoski, Andrew J., Ian Moult, and Duff Neill. “Analytic Boosted Boson Discrimination.” Journal of High Energy Physics 2016.5 (2016): n. pag.

Version: Final published version

ISSN

1029-8479

1126-6708