Lecture

Optical Methods in Chemistry

Related lectures (32)

Optical Methods in Chemistry: Microscopy, Manipulation, Spectroscopy

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

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

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.

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.

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.

Optical Principles

Covers fundamental principles of ray and wave optics, including reflection, interference, diffraction, and spectroscopy.

Cavities and Lasers

Explores the principles of cavities and lasers, including Fabry-Perot resonators, Gaussian beams, cavity configurations, and absorption-emission-stimulated emission processes.

Optical Spectroscopy: Fundamentals and Applications

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

Laser Micro-Processing: Materials and Spectroscopy

Explores laser micro-processing of materials, fluorescence, spectroscopy, and band structures.

Electron Oscillator Model: Lorentz Model

Introduces the electron oscillator model and its impact on electromagnetic wave propagation.

Introduction to X-rays and X-ray Sources: Part 3

Explores synchrotron radiation, X-ray sources, scientific achievements, and recent highlights in synchrotron science.

Ray Optics: EM Wave Optics

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

Laser Fundamentals: Gain, Absorption, and Resonators

Explains the principles of laser operation, focusing on gain, absorption, and the role of resonators in achieving lasing.

Basic concepts of photons and x-rays

Explores the interaction of x-rays with matter, matching photon energy, and ionizing radiation.

Spectroscopy Fundamentals

Covers the fundamentals of spectroscopy and color drawing techniques.

Light Dosimetry in Tissues

Explores light dosimetry in tissues for photomedicine applications, covering mechanisms of light therapy, laser classification, and the influence of laser parameters on treatment outcomes.

Chirped Pulse Amplification: Ultrashort Laser Pulses

Explores chirped pulse amplification for ultrashort laser pulses and the significance of Carrier-Envelope Phase stabilization.

Spectroscopy: Light Propagation and Absorption

Explores spectroscopy, light propagation, and absorption processes in molecules.

Beam Optics: Introduction and Applications

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

Laser Systems: Theory and Applications

Covers the basic principles of laser operation, types of laser systems, noise characteristics, optical fibers, ultrafast lasers, and modern applications.