Explores the historical development and industrial applications of radiography and computerized tomography with X-rays, gammas, and neutrons.
Explores radiation sources, including fast electrons, heavy charged particles, and neutrons, discussing their applications and characteristics.
Introduces optical methods in chemistry, covering ray optics, lasers, spectroscopy, and X-ray physics, emphasizing light-matter interactions and Nobel Prize-winning advancements.
Explores interference, reflection, diffraction, fog effects, antennas, noise, EIRP, and link assessment in radiation and antennas.
Explores X and gamma-ray imaging devices, detector types, energy resolution, and charge transport mechanisms.
Covers the properties of synchrotron radiation, including its emission by relativistic particles and its effect on the beam through radiation damping.
