Extensible Quantum Computing Architectures with van der Waals Heterostructures

Mostafa Kamal

José Gabriel Carrasco Ramírez


Abstract

This study proposes a novel theoretical framework for developing scalable and extensible quantum computing architectures using van der Waals (vdW) heterostructures, with a focus on graphene-based materials. Leveraging the unique electrical and material properties of 2D materials, this work introduces innovative qubit configurations designed to enhance the scalability, robustness, and operational efficiency of quantum computing systems. Key contributions include the assessment of qubit operability within vdW heterostructures through quantum mechanical modeling, evaluation of quantum coherence to counteract decoherence mechanisms, and simulation of qubit manipulation in response to external stimuli. The research outlines a path toward integrating vdW heterostructures with existing quantum computing technologies to form hybrid systems, highlighting the potential for increased computational capabilities and versatility. The proposed designs are examined for their operational viability and robustness against quantum errors, with findings suggesting promising avenues for scalability and integration with broader quantum systems. This paper sets the stage for future experimental validation and optimization, aiming to bridge the gap between theoretical potential and practical quantum computing applications.


Author Biography

José Gabriel Carrasco Ramírez

PhD (c) and Msc in International Law and International Studies.

Caribbean International University, Curazao, Lawyer.

Universidad Católica Andrés Bello, Caracas, Venezuela.

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