Yves Marc Acremann: Catalogue data in Spring Semester 2018 |
Name | PD Dr. Yves Marc Acremann |
Field | Experimental physics |
Address | Laboratorium für Festkörperphysik ETH Zürich, HPF C 5 Otto-Stern-Weg 1 8093 Zürich SWITZERLAND |
Telephone | +41 44 633 23 56 |
acyves@ethz.ch | |
Department | Physics |
Relationship | Privatdozent |
Number | Title | ECTS | Hours | Lecturers | |
---|---|---|---|---|---|
402-0040-00L | Physics I | 5 credits | 4V + 2U | Y. M. Acremann, D. Pescia | |
Abstract | Part A: Introduction to mechanics, wave phenomena, Kelpler problem, rotational motion. Part B: electrostatics of metals and isolators, magnetostatics, Maxwell equations. | ||||
Objective | Fundamentals of mechanics, oscillations, waves, electrostatics and magnetostatics. | ||||
Content | Part A: Introduction to mechanics, wave phenomena, Kelpler problem, rotational motion. Part B: electrostatics of metals and isolators, magnetostatics, Maxwell equations. | ||||
Lecture notes | A copy of the blackboard is made available online. | ||||
Literature | (Fakultativ): Teil A: W. Nolting, "Klassische Mechanik", Springer Verlag, Berlin, 2011. Teil B: W. Nolting, "Elektrodynamik", Springer Verlag, Berlin, 2011 | ||||
402-0528-12L | Ultrafast Methods in Solid State Physics | 6 credits | 2V + 1U | Y. M. Acremann, S. Johnson | |
Abstract | This course provides an overview of experimental methods and techniques used to study dynamical processes in solids. Many processes in solids happen on a picosecond to femtosecond time scale. In this course we discuss different methods to generate femtosecond photon pulses and measurement techniques adapted to time resolved experiments. | ||||
Objective | The goal of the course is to enable students to identify and evaluate experimental methods to manipulate and measure the electronic, magnetic and structural properties of solids on the fastest possible time scales. These "ultrafast methods" potentially lead both to an improved understanding of fundamental interactions in condensed matter and to applications in data storage, materials processing and computing. | ||||
Content | The topical course outline is as follows: 0. Introduction Time scales in solids and technology Time vs. frequency domain experiments Pump-Probe technique 1. Ultrafast processes in solids, an overview Electron gas Lattice Spin system 2. Ultrafast optical-frequency methods Ultrafast laser sources Broadband techniques Harmonic generation, optical parametric amplification Fluorescence Advanced pump-probe techniques 3. THz-frequency methods Mid-IR and THz interactions with solids Difference frequency mixing Optical rectification 4. Ultrafast VUV and x-ray frequency methods Synchrotron based sources Free electron lasers Higher harmonic generation based sources X-ray diffraction Time resolved X-ray microscopy Coherent imaging 5. Electron spectroscopy in the time domain | ||||
Lecture notes | Will be distributed. | ||||
Literature | Will be distributed. | ||||
Prerequisites / Notice | Although the course "Ultrafast Processes in Solids" (402-0526-00L) is useful as a companion to this course, it is not a prerequisite. |