Von Neumann algebras are collections of infinite matrices with complex entries and were initially developed to provide a rigorous mathematical framework for quantum mechanics. Early work by pioneers of the field during the 1930s and 1940s revealed that von Neumann algebras are highly complex objects exhibiting remarkably rich structural properties. Over time, their study evolved into an independent and vibrant area of mathematics, spurring the development of powerful mathematical theories and uncovering deep connections with other fields such as group theory, dynamical systems, topology, and more recently, model theory. Beyond mathematics, von Neumann algebras have also provided valuable insights in physics (notably statistical mechanics), biology (DNA molecular structure), engineering (cell phone network design), and computer science (including error-correcting codes, quantum information theory, and quantum computing). These algebras naturally arise from simpler mathematical concepts like groups (symmetries) and their actions on spaces, which are extensively studied in geometric group theory and ergodic theory. The project investigates a number of open problems, with the central goal of developing new methods at the intersection of these disciplines to advance the classification of von Neumann algebras arising from such structures. Additionally, the project offers extensive opportunities for graduate student training and career development. Building on the PI’s prior work