Strongly Correlated Systems are materials in which interactions between electrons dominate their behavior. In these systems, electrons cannot be treated as independent particles. Strong correlations lead to exotic phenomena such as metal–insulator transitions, unconventional superconductivity, and complex magnetic order. Traditional band theory often fails to describe these materials accurately. Strongly correlated systems are central to condensed-matter physics and many-body theory. They include transition metal oxides, heavy-fermion compounds, and some low-dimensional materials. Studying these systems helps uncover new phases of matter and emergent behavior. Strong correlations highlight how collective effects can drastically alter material properties. This field remains one of the most challenging and intellectually rich areas of modern physics.
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