Quantum Control and Gate Optimization in Graphane-Based Quantum Systems
Abstract
In this study, we investigate the application of graphane, a novel material evolved from graphene through hydrogenation, in the domain of quantum computing. Our focus is on developing and refining quantum control schemes tailored for graphane-based systems, aiming to harness its distinctive properties for quantum technology advancement. The research encompasses theoretical modeling of advanced control protocols, extensive numerical simulations for protocol evaluation, and proposed experimental frameworks for real-world applicability assessment. Central to our objectives is the enhancement of gate fidelity, the scalability of quantum systems, and the mitigation of decoherence and operational errors. Preliminary results from numerical simulations indicate significant improvements in gate fidelity, underscoring the potential of our optimized control schemes to elevate quantum computing capabilities, particularly within graphane-based architectures. Our findings also suggest favorable scalability prospects for graphane-based quantum systems, alongside robustness against common quantum computing challenges. This investigation highlights graphane's promise as a quantum computing platform and sets a foundation for future explorations into novel materials and control strategies, aiming to advance the field of quantum technologies.