Glass Transition, Quantum Tunneling, and Directional Transport in Random Energy Landscapes: A Comprehensive Numerical and Theoretical Study

The glass transition and amorphous state dynamics constitute fundamental challenges in condensed matter physics and physical chemistry. This work presents a comprehensive numerical and theoretical study of particle motion in random energy landscapes, with a particular focus on the interplay between quantum tunneling and directional asymmetric potentials [Yildirim, 2025]. The analysis includes a review of state-of-the-art theories, a detailed numerical model, graphical results, and a critical discussion of implications for experimental glass science. Figures, code, and supplementary analysis are provided.

Originality and AI-use statement:
This work is an original research output by Begüm Yıldırım. AI tools, if used, were limited to language refinement, grammar correction, formatting, translation assistance, and clarity improvement. The conceptual framework, research direction, interpretation, models, and conclusions belong to the author. External sources, datasets, or prior works are cited where applicable.