Covers the principles of mass transfer, including diffusion and Fick's equations, and their applications in various processes.
Explores diffusion mechanisms in crystalline solids, covering cubic and non-cubic structures, temperature effects, and self-diffusion in metals.
Explores mass transfer coefficients in liquid and gas phases, with a focus on convective mass transfer around dissolving bubbles and experimental dynamics of granular systems.
Explores heterodiffusion in solids, discussing electrolyte diffusion, solute diffusion in crystals, crystal structures, and diffusion coefficients.
Explores mass transfer, Fick's laws, Nernst-Einstein equation, and transport forces in various desorption and absorption examples.
Explores autodiffusion in metals, covering temperature and pressure influence, empirical correlations, and different metal structures.
Explores diffusion, transport phenomena, Fick's law, thermal and electrical transport, Onsager's relations, and thermoelectric effects.
Explores electrolyte diffusion in liquids and solids, emphasizing heterodiffusion mechanisms and solute interactions in crystal structures.
Explores mass transfer in electrochemistry, covering diffusion, migration, convection, Nernst Planck equation, linear diffusion approximations, and transient response.
Explores diffusion from a macroscopic perspective, emphasizing the derivation of the diffusion equation through mass conservation and fixed flux law.
Covers the solutions of neutron diffusion, including analytical solutions, Laplacian in different geometries, and the physical significance of the diffusion area.
Explores the microscopic description of diffusion and convection transport, emphasizing similarities between chemical diffusion and heat conduction.
