The main purpose of the Master Project Proposal is to help students organize ideas, material and objectives for their Master Thesis, and to begin development of communication skills. An integral part of the MSc Project Proposal is the lecture on Conduct as a Scientist.

Project in a research group at ETH or at an University of 12 weeks. The project is completed with a written report.

Independent scientific practice of 8 weeks which is completed with a written report.

Working during one semester on a task on a topic in the chosen major

Working on a concrete task in Construction Engineering

Working on a concrete task in Construction and Maintenance Management

Working during one semester on a task on Material Flow and Waste Management

Working on a concrete task in Geotechnical Engineering

Working on a concrete task in Hydraulic Engineering

Working on a concrete task in Hydraulic Engineering and Water Resources Management

Working on a concrete task in Materials and Mechanics

Working during one semester on a task on Soil Protection

Working on a concrete task on Transport Systems

Working during one semester on a task on Urban Water Management

Working during one semester on a task on Water Ressources Management

No description available.

The QuanTech Workshops are a project-oriented learning environment in the context of quantum technology. Students work in teams, consisting of engineers and physicists, and jointly tackle a quantum engineering project. During the preceding course "Case Studies: Application of Quantum Technologies", students develop project proposals. Successful proposals will be realized in a QuanTech Workshop.

General structure of quantum theory: Hilbert spaces, states and observables, equations of motion, Heisenberg uncertainty relation, symmetries, angular momentum addition, EPR paradox, Schrödinger and Heisenberg picture.Applications: simple potentials in wave mechanics, scattering and resonance, harmonic oscillator, hydrogen atom, and perturbation theory.

Classical and semi-classical introduction to Quantum Electronics. Mandatory for further elective courses in Quantum Electronics. The field of Quantum Electronics describes propagation of light and its interaction with matter. The emphasis is set on linear wave and beam propagation in dispersive media, interference, diffraction, optical anisotropic materials, waveguides and lasers.

Classical and semi-classical introduction to Quantum Electronics. Mandatory for further elective courses in Quantum Electronics. The field of Quantum Electronics describes propagation of light and its interaction with matter. The emphasis is set on linear pulse and beam propagation in dispersive media, optical anisotropic materials, and waveguides and lasers.