Strong Interactions bind quarks together to form hadrons and hold atomic nuclei intact. This force is described by quantum chromodynamics and is mediated by gluons. Strong interactions are characterized by confinement, which prevents quarks from existing freely, and asymptotic freedom, where interactions weaken at high energies. Strong interactions dominate nuclear structure, hadron formation, and high-energy particle collisions. Understanding strong interactions requires advanced theoretical and computational methods due to their nonlinear nature. They govern phenomena ranging from proton stability to quark–gluon plasma formation. Experimental studies involve deep inelastic scattering and heavy-ion collisions. Strong interactions play a fundamental role in shaping visible matter and remain a central focus of particle and nuclear physics research.
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