13 laser positions at ETH Zurich

Postdoctoral researcher in ultrahigh-pressure mineral physics and geophysics at ETH Zurich

temperature experimental work using a laser-heated or externally-heated diamond anvil cell combined with various laser spectroscopic methods (Raman, Brillouin scattering) and synchrotron X-rays to determine the physical

Postdoc positions in Experimental Quantum Engineering Group

description As a postdoc in this role, you will be at the forefront of quantum science and quantum technologies. Your responsibilities will include setting up laser systems for coherent Rydberg state

Research assistant with possibility for PhD – Optimization of Railway using Artificial Intelligence with Physical Models

of acoustic roughness. This project explores the feasibility of a non-contact measurement approach using optical laser triangulation sensors to gauge rail roughness from moving trains. Your profile You have to

PhD position in ultrafast imaging on ferroic materials

technological relevance. Our experimental core technology is pulsed-laser spectroscopy between Terahertz and ultraviolet frequencies. In addition, we apply atomic force microscopy, standard magnetic and

Research Associate – Development of processing strategies for ceramic-metal additive manufacturing

metals by laser powder bed fusion (LPBF). Job description The main goal of your work is to develop a new process for LPBF of ceramics and copper alloys for electrical applications. The research project is

PhD Positions in Levitated Optomechanics

students to join our levitodynamics team. Your profile Physics or engineering background Experience with experimental work in particular with lasers and measurement techniques The successful candidate shares

Postdoctoral Positions in Levitated Optomechanics

to join our levitodynamics team. Your profile Physics or engineering background Experience with experimental work in particular with lasers and measurement techniques The successful candidate shares our

Postdoctoral position in Terahertz dynamics on strongly correlated materials

technological relevance. Our experimental core technology is pulsed-laser spectroscopy between Terahertz and ultraviolet frequencies. In addition we apply atomic force microscopy, standard magnetic and dielectric

PhD position in Terahertz dynamics on strongly correlated materials

technological relevance. Our experimental core technology is pulsed-laser spectroscopy between Terahertz and ultraviolet frequencies. In addition we apply atomic force microscopy, standard magnetic and dielectric

PhD position in nonlinear laser spectroscopy on altermagnets

technological relevance. Our experimental core technology is nonlinear optical spectroscopy with pulsed lasers. In addition we apply atomic force microscopy, standard magnetic and dielectric characterization