Explores Tissue Optics, focusing on Optical Coherence Tomography and light scattering in photomedicine, with applications in ophthalmology, dermatology, cardiology, and gastroenterology.
Discusses charge transport in semiconductors, covering mobility, scattering phenomena, and the engineering of one-dimensional channels in two-dimensional electron gases.
Explores gauge symmetry, amplitudes, black holes, and fluids, highlighting the interplay between redundancy, diffeomorphisms, and the double copy phenomenon.
Explores applications of stimulated scatterings in optical fibers, including power probing, distributed sensing, slow & fast light, and optical storage.
Covers Brillouin scattering, a powerful tool in photonics, explaining material density fluctuations' impact on light and the optical effects of inelastic scatterings.
Explores modeling multilayer 2D materials, tight-binding models, and electrical conductivity in materials, emphasizing the importance of symmetries and reduced models.
Discusses the radiative properties of particulate media, focusing on Mie theory and its practical applications in analyzing light interactions with particles.
Explores the Radiative Transport Equation in tissue optics, covering radiance, photon distribution, and numerical solutions like Monte Carlo simulations.
Explores ptychography, a powerful imaging technique used in synchrotrons and x-ray free-electron lasers, covering its principles, applications, and experimental considerations.
