Lecture

Optical Principles

Related lectures (32)

Explores the principles of lasers, including lasing transitions and optical tweezers, with applications in various fields.

Optical Tweezers: Basics and Applications

Covers the basics of optical tweezers and their applications in microscopy, manipulation, and spectroscopy, as well as the alignment of molecules using laser pulses.

Optical Methods in Chemistry: Microscopy, Manipulation, Spectroscopy

Explores optical methods in chemistry, covering microscopy, manipulation, and spectroscopy techniques.

Beam Optics: Introduction and Applications

Covers beam optics, Gaussian beams, and wavefront curvature in various applications.

Optical Methods in Chemistry

Introduces optical methods in chemistry, covering ray optics, lasers, spectroscopy, and X-ray physics, emphasizing light-matter interactions and Nobel Prize-winning advancements.

Fourier Optics: Wavefront Analysis

Explores Fourier optics, diffraction principles, Fourier analysis, and the application of Fourier transform in optics.

Ultrafast Lasers and Non-linear Optics

Covers ultrafast lasers, non-linear optics, mode selection, cavity dumping, and chirped pulse amplification, exploring Nobel Prize-winning contributions in physics and chemistry.

X-rays: From Discovery to Applications

Explores the historical perspective, properties, and applications of X-rays, including diffraction, atomic resolution, and spectral colors of elements.

Introduction to Optics: Light and Waves

Introduces fundamental optics concepts, covering refraction, reflection, interference, polarization, and more, exploring the behavior of light in different media.

Electromagnetic Waves: Reflection, Refraction, and Interference

Explores electromagnetic waves, wave optics, interference, and diffraction phenomena in experimental physics II.

Ray Optics: EM Wave Optics

Explores radiometry, photometry, laser power distribution, and light behavior in different media.

Electromagnetic Waves and Optics

Covers electromagnetic fields, wave optics, wave interference, diffraction, induction, historical debates on light theories, the electromagnetic spectrum, and wave superposition.

Electromagnetic Waves and Optics

Covers the fundamentals of electromagnetic waves and optics, including interference phenomena, diffraction, refraction, and reflection of light.

Optics: Introduction

Introduces geometric, wave, and electromagnetic optics in a series of three courses.

Optical Spectroscopy: Fundamentals and Applications

Covers the fundamentals of optical spectroscopy and its applications in various fields, exploring the design and operation of spectrometers.

Introduction to Optics: Basics and Applications

Introduces the fundamental concepts of optics, covering quantum optics, wavy optics, and electromagnetic optics, as well as the principles of reflection, refraction, and image formation.

Diffraction: Basics

Covers the basics of diffraction phenomena, diffraction patterns, gratings, the diffraction limit, and X-ray techniques.

Electromagnetic Fields and Optics

Explores electromagnetic fields, forces, waves, optics, interference, diffraction, refraction, reflection, lenses, and instruments.

Spatial Frequencies and Wave Propagation

Explores spatial frequencies, wave propagation, diffraction phenomena, and optical filtering techniques.

Beamlines: Elements of Front Ends and Optics

Explores the basic elements of optics theory, edge diffraction, and limits to focusing light.