Automating methods to improve precision in Monte-Carlo event generation for particle colliders / Automatisierung von Methoden zur Verbesserung der Praezision bei der Monte-Carlo Eventgeneration fuer Teilchenbeschleunigerexperimente

Gleisberg, Tanju

24 April 2008

This thesis concerns with numerical methods for a theoretical description of high energy particle scattering experiments. It focuses on fixed order perturbative calculations, i.e. on matrix elements and scattering cross sections at leading and next-to-leading order. For the leading order a number of algorithms for the matrix element generation and the numeric integration over the phase space are studied and implemented in a computer code, which allows to push the current limits on the complexity of the final state and the precision. For next-to-leading order calculations necessary steps towards a fully automated treatment are performed. A subtraction method that allows a process independent regularization of the divergent virtual and real corrections is implemented, and a new approach for a semi-numerically evaluation of one-loop amplitudes is investigated.

theoretical particle physics

event simulation

matrix element generation

Monte-Carlo

theoretische Teilchenphysik

Eventsimulation

Matrixelementgenerierung

Monte-Carlo

ddc:530

rvk:UN 6100

Automating methods to improve precision in Monte-Carlo event generation for particle colliders

Gleisberg, Tanju

17 March 2008

This thesis concerns with numerical methods for a theoretical description of high energy particle scattering experiments. It focuses on fixed order perturbative calculations, i.e. on matrix elements and scattering cross sections at leading and next-to-leading order. For the leading order a number of algorithms for the matrix element generation and the numeric integration over the phase space are studied and implemented in a computer code, which allows to push the current limits on the complexity of the final state and the precision. For next-to-leading order calculations necessary steps towards a fully automated treatment are performed. A subtraction method that allows a process independent regularization of the divergent virtual and real corrections is implemented, and a new approach for a semi-numerically evaluation of one-loop amplitudes is investigated.

info:eu-repo/classification/ddc/530

ddc:530