Transformative Potential of Quantum Simulation in Chemistry and Materials Science: Advances, Applications, and Future Directions

Wanjiku Amani Njoki

Faculty of Engineering Kampala International University Uganda

ABSTRACT

Quantum simulation, utilizing quantum computers to model complex quantum systems, offers transformative capabilities in chemistry and materials science. This review explores both digital and analog quantum simulation methodologies, highlighting their advances, applications, and future directions. Digital methods such as the Variational Quantum Eigensolver (VQE) and Quantum Approximate Optimization Algorithm (QAOA) excel in calculating molecular properties and optimizing material designs, leveraging quantum bits to surpass classical computing limitations. Analog techniques simulate quantum systems through physical analogies, offering insights into emergent quantum behaviors in systems like cold atoms and trapped ions. In East Africa, quantum simulation research is burgeoning, with institutions like the African Institute for Mathematical Sciences (AIMS) and the University of Nairobi leading initiatives. Challenges such as limited quantum hardware access and skill gaps necessitate robust infrastructure and educational programs. Future directions envision regional centers of excellence, collaborative ecosystems, and innovative applications addressing local challenges. Quantum simulation stands poised to revolutionize scientific inquiry, technological innovation, and regional development, positioning East Africa at the forefront of quantum research’s transformative impact on society.

Keywords: Transformative Potential, Quantum Simulation, Chemistry, Materials Science.

CITE AS: Wanjiku Amani Njoki (2024).Transformative Potential of Quantum Simulation in Chemistry and Materials Science: Advances, Applications, and Future Directions. IDOSR JOURNAL OF COMPUTER AND APPLIED SCIENCES 9(1):27-32.  https://doi.org/10.59298/JCAS/2024/91.152732001