In this thesis, I calculate the spin-dependent next-to-leading order QCD corrections to the diffe... more In this thesis, I calculate the spin-dependent next-to-leading order QCD corrections to the differential scattering cross section for W boson production by proton-proton collisions. Apart from the relevant Feynman diagrams, the crossing functions are derived as well, allowing a complete description of the hadronic scattering cross section to NLO as a function of hadron polarisation. This quantity can be used to calculate the polarisation asymmetry, which is very well suited for direct experimental measurement. Exploiting this possibility to directly compare theoretical results with experimental findings, one will be able to gain deeper insight into the spin-dependent parton distribution functions, which in turn will help in making further progress towards solving the proton spin puzzle.
The causal approach to perturbative quantum field theory is presented in detail, which goes back ... more The causal approach to perturbative quantum field theory is presented in detail, which goes back to a seminal work by Henri Epstein and Vladimir Jurko Glaser in 1973. Causal perturbation theory is a mathematically rigorous approach to renormalization theory, which makes it possible to put the theoretical setup of perturbative quantum field theory on a sound mathematical basis. Epstein and Glaser solved this problem for a special class of distributions, the time-ordered products, that fulfill a causality condition, which itself is a basic requirement in axiomatic quantum field theory. In their original work, Epstein and Glaser studied only theories involving scalar particles. In this review, the extension of the method to theories with higher spin, including gravity, is presented. Furthermore, specific examples are presented in order to highlight the technical differences between the causal method and other regularization methods, like, e.g. dimensional regularization.
Continuum states of the Dirac equation are calculated numerically for the electrostatic field gen... more Continuum states of the Dirac equation are calculated numerically for the electrostatic field generated by the charge distribution of an atomic nucleus. The behavior of the wave functions of an incoming electron with given asymptotic momentum in the nuclear region is discussed in detail and the results are compared to different approximations used in the data analysis for quasielastic electron scattering off medium and highly charged nuclei. It is found that most of the approximations provide an accurate description of the electron wave functions in the range of electron energies above 100 MeV typically used in experiments for quasielastic electron scattering off nuclei only near the center of the nucleus. It is therefore necessary that the properties of exact wave functions are investigated in detail in order to obtain reliable results in the data analysis of quasielastic (e, e p) knockout reactions or inclusive quasielastic (e, e) scattering. Detailed arguments are given that the effective momentum approximation with a fitted potential parameter is a viable method for a simplified treatment of Coulomb corrections for certain kinematical regions used in experiments. Numerical calculations performed within the framework of the single-particle shell model for nucleons lead to the conclusion that our results are incompatible with calculations performed about a decade ago, where exact electron wave functions were used in order to calculate Coulomb corrections in distorted-wave Born approximation. A discussion of the exact solutions of the Dirac equation for free electrons in a Coulomb field generated by a point-like charge and some details relevant for the numerical calculations are given in the appendix.
JRODOS is a modular decision support system intended for use in radiological emergency protection... more JRODOS is a modular decision support system intended for use in radiological emergency protection. Switzerland has implemented this software as primary prognosis tool for the impact assessment of radiological emergencies at nuclear installations. Here we present the current status of the software, the implementation in Switzerland, and give an outlook on further developments.
In this thesis, I calculate the spin-dependent next-to-leading order QCD corrections to the diffe... more In this thesis, I calculate the spin-dependent next-to-leading order QCD corrections to the differential scattering cross section for W boson production by proton-proton collisions. Apart from the relevant Feynman diagrams, the crossing functions are derived as well, allowing a complete description of the hadronic scattering cross section to NLO as a function of hadron polarisation. This quantity can be used to calculate the polarisation asymmetry, which is very well suited for direct experimental measurement. Exploiting this possibility to directly compare theoretical results with experimental findings, one will be able to gain deeper insight into the spin-dependent parton distribution functions, which in turn will help in making further progress towards solving the proton spin puzzle.
The causal approach to perturbative quantum field theory is presented in detail, which goes back ... more The causal approach to perturbative quantum field theory is presented in detail, which goes back to a seminal work by Henri Epstein and Vladimir Jurko Glaser in 1973. Causal perturbation theory is a mathematically rigorous approach to renormalization theory, which makes it possible to put the theoretical setup of perturbative quantum field theory on a sound mathematical basis. Epstein and Glaser solved this problem for a special class of distributions, the time-ordered products, that fulfill a causality condition, which itself is a basic requirement in axiomatic quantum field theory. In their original work, Epstein and Glaser studied only theories involving scalar particles. In this review, the extension of the method to theories with higher spin, including gravity, is presented. Furthermore, specific examples are presented in order to highlight the technical differences between the causal method and other regularization methods, like, e.g. dimensional regularization.
Continuum states of the Dirac equation are calculated numerically for the electrostatic field gen... more Continuum states of the Dirac equation are calculated numerically for the electrostatic field generated by the charge distribution of an atomic nucleus. The behavior of the wave functions of an incoming electron with given asymptotic momentum in the nuclear region is discussed in detail and the results are compared to different approximations used in the data analysis for quasielastic electron scattering off medium and highly charged nuclei. It is found that most of the approximations provide an accurate description of the electron wave functions in the range of electron energies above 100 MeV typically used in experiments for quasielastic electron scattering off nuclei only near the center of the nucleus. It is therefore necessary that the properties of exact wave functions are investigated in detail in order to obtain reliable results in the data analysis of quasielastic (e, e p) knockout reactions or inclusive quasielastic (e, e) scattering. Detailed arguments are given that the effective momentum approximation with a fitted potential parameter is a viable method for a simplified treatment of Coulomb corrections for certain kinematical regions used in experiments. Numerical calculations performed within the framework of the single-particle shell model for nucleons lead to the conclusion that our results are incompatible with calculations performed about a decade ago, where exact electron wave functions were used in order to calculate Coulomb corrections in distorted-wave Born approximation. A discussion of the exact solutions of the Dirac equation for free electrons in a Coulomb field generated by a point-like charge and some details relevant for the numerical calculations are given in the appendix.
JRODOS is a modular decision support system intended for use in radiological emergency protection... more JRODOS is a modular decision support system intended for use in radiological emergency protection. Switzerland has implemented this software as primary prognosis tool for the impact assessment of radiological emergencies at nuclear installations. Here we present the current status of the software, the implementation in Switzerland, and give an outlook on further developments.
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Papers by Cyrill von Arx