Explores the radiative properties of small spheres, including Rayleigh scattering and absorption efficiencies, with a focus on Mie theory and particle characteristics.
Discusses the radiative properties of particulate media, focusing on Mie theory and its practical applications in analyzing light interactions with particles.
Discusses radiative transfer in participating media, focusing on key concepts like attenuation, extinction coefficients, and the radiative transfer equation.
Discusses the radiative properties of particles, focusing on Rayleigh and Mie scattering theories and their applications in understanding light behavior.
Explores radiative heat transfer equilibrium between walls and isotropic scattering medium, optical thickness, Monte Carlo method, and analytical solutions.
Explores radiative heat transfer principles in the presence of conduction and convection, covering surface exchange, coupled heat transfer, thermocouples, and gas flow.
Explores the Radiative Transport Equation in tissue optics, covering radiance, photon distribution, and numerical solutions like Monte Carlo simulations.
Explores Tissue Optics, focusing on Optical Coherence Tomography and light scattering in photomedicine, with applications in ophthalmology, dermatology, cardiology, and gastroenterology.
Explores analytical and Monte Carlo solutions for radiative heat transfer in isotropically scattering media at radiative equilibrium between gray and diffuse walls.
