Research colloquium, with a particular emphasis on IPA-related research topics.

Microanalytics of proteins and proteomes. Edman sequencing and chemical modification of proteins, modern proteome analytics, including MALDI-TOF and electrospray mass spectrometry, HPLC separation of peptides after proteolytic proteome digestion. Actual lieterature in protein chemistry.

Mechanisms of biomacromolecular recognition. The basics of protein, DNA and RNA structures and their complexes are described, with special emphasis on functionality and energetic aspects.

Molekular biology and Biophysics III: Biophysics of protein folding, membrane proteins and biophysics of membranes, enzymatic catalysis, katalytic RNA and RNAi, proteome analytics, actual literature in protein biophysics and structural biology

Introduction to neutron scattering (mathematical description in terms of correlation functions) and applications to basic problems of solid state physics: static and dynamics of condensed matter, magnetic structures as well as magnetic excitations, polarized neutrons.

The goal of the course is to provide the physics and technology basis for controlled fusion research, from the main elements of plasma physics to the reactor concepts.

This lecture conveys the mathematical basis necessary for the development and application of numerical models in the field of Environmental Science. The lecture material includes an introduction into numerical techniques for solving ordinary and partial differential equations, as well as exercises aimed at the realization of simple models using the computer language Python.

Have you ever wondered how to solve environmentally relevant problems using a computer? In this lecture, we explore methods that form the foundation of modern weather, hydrology, and ecology models. You'll learn the basics of numerical mathematics and widely used algorithms, applying your knowledge by programming simple models in Python.

This course offers a project-based alternative to the conventional physics lab course. Students can plan, build, carry out, and evaluate their own physics experiments.

Following topics are treated:matter and fields; symmetries and groups;recapitulation of important aspects of non-relativistic QM;electrodynamik of spinless particles; Feynman diagrams and propagators;concept of spin; Dirac equation; electrodynamik of particles with spin;Feynman rules;structure of hadrons and its measurement in deep-inelastic scattering.

The course focuses on the connection between particle physics theory and experimental results to provide a comprehensive modern view of the Standard Model. The covered topics are quantum electrodynamics (QED) and quantum chromodynamics (QCD).

Research colloquium

Detailed information in:http://[email protected]/~nessif/ETHTeilchenpraktikumCERN.html

An introduction to key concepts on the interface of Particle Physics and Early Universe cosmology. Topics include inflation and inflationary models, the ElectroWeak phase transition and vacuum stability, matter-antimatter asymmetry, recombination and the Cosmic Microwave Background, relic abundances and primordial nucleosynthesis, baryogenesis, dark matter and more.