Upon completing this course, students should have acquired the fundamental concepts of classical electrodynamics, including both its non-relativistic and relativistic components, and should be able to apply these concepts to the analysis and resolution of problems.
Carry out advanced experimental work in frontier areas of physics within research laboratory environments associated with research units. Acquire experimental techniques specific to measurement and analysis in these different areas of physics, while also developing the foundational knowledge and experimental skills necessary for the design and execution of new experiments.
Statistical analysis of scalar or vector data, spectral analysis. Fast imaging – Intensified imaging – Slit scanning – Optical Emission Spectroscopy (OES) – Actinometry – Chemiluminescence – Line profile analysis – Absorption spectroscopy – Tunable Diode Laser – Saturation – Laser-Induced Fluorescence (LIF) – Two-photon fluorescence (TALIF) – Advanced optical diagnostics (absolute OES, CRDS, IR absorption, etc.) Langmuir probe – Microwave techniques and hairpin probe – Resistive and capacitive measurements of discharge currents.