John M. Campbell, Walter T. Giele, Ciaran Williams
Published 2013-11-22Version 1
We present a general method of associating next-to-leading order weights to leading order phase space configurations at hadron colliders. The method relies on a re-organization of phase space for the real radiation contributions, defining a one-to-many map such that each point in the real phase space is associated with a distinct Born topology. As a result virtual and real singularities cancel at each Born phase space point. The new phase space maps can be used in a traditional approach for NLO calculations. However, interesting applications arise when one instead integrates out the real radiation up to a specified scale. This allows one to define NLO weights for individual phase space points that are present at LO. This method allows for the extension of matrix element methods to next-to-leading order, even in the presence of jets. We discuss some recent applications of the matrix element method to Higgs physics at the LHC.
Comments: 8 pages, 1 figure, Talk presented at 11th International Symposium on Radiative Corrections (Applications of Quantum Field Theory to Phenomenology) (RADCOR 2013)
Extending the Matrix Element Method to Next-to-Leading Order
The matrix element method at next-to-leading order for arbitrary jet algorithms
Finding the Higgs boson in decays to Z gamma using the matrix element method at Next-to-Leading Order
![QR code for arXiv:1311.5811 [hep-ph]](http://oss.arxitics.com/images/favicon.svg)