Physics

Superallowed beta decay is a highly symmetric radioactive process where a neutron converts to a proton or vice versa, emitting a beta particle and a neutrino, crucial for testing fundamental physics laws.

Nuclear biophysics investigates the interactions and effects of nuclear phenomena within biological systems, linking physics and biology at the atomic level.

Nuclear astrometry is a field that studies nuclear processes in stars, focusing on nuclear fusion and nucleosynthesis to understand element formation in the universe.

Explore wave drag in fluid mechanics, its causes, effects, and advanced reduction strategies in aviation and naval engineering for efficiency.

Nuclear vorticity refers to the rotational characteristics and angular momentum within atomic nuclei, influencing nuclear dynamics and structure.

Isoscalar Giant Resonances (IGR) are high-energy, short-lived states in atomic nuclei, involving coherent nucleon oscillations, crucial for understanding nuclear matter properties.

Unveiling the unique “nuclear pasta” phase in neutron star crusts, where matter organizes into structures reminiscent of common pasta shapes due to extreme densities and forces.

Understanding delayed neutron precursors is crucial in nuclear reactor control and safety mechanisms.

Proton radiography is an advanced imaging technique using high-energy protons to capture detailed internal structural and compositional information of objects in fields like medical imaging and materials science.

Neutron radiography is an imaging technique using neutrons instead of X-rays, revealing details hidden in other methods.