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Abstract
This thesis presents advancements in computational methodologies to enhance molecular simulations through the development of active learning techniques, machine-learning methods, and robust open-source software engineering with a focus on ML-integration. The research is organized around four primary contributions: (1) computational modeling of self-assembling peptide--$\pi$ conjugated systems to guide the design of supramolecular nanomaterials, (2) the development and implementation of Permutationally Invariant Networks for Enhanced Sampling (PINES), (3) the high-throughput virtual screening of DNA-functionalized nanoparticles (DFPs) using an active learning approach, and (4) the structured software development of the PINES and ALPineFOREst frameworks.