Guest Editor(s)
Dr. Fernaz Narin Nur
Email: fernaznn@gmail.com
Affiliation: Department of Computer Science & Engineering (CSE), Faculty of Electrical and Computer Engineering, Military Institute of Science and Technology (MIST), Mirpur Cantonment, Dhaka, Bangladesh
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Research Interests: network security, quantum computing, wireless network, IoT, AI
Prof. Selina Sharmin
Email: selina@cse.jnu.ac.bd
Affiliation: Department of CSE, Jagannath University, Bangladesh
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Research Interests: networking, cloud computing, sensor network, machine learning
Dr. Ismail Olaniyi Muraina
Email: niyi4edu@gmail.com
Affiliation: Department of Computer Science, Lagos State University of Education, Oto, Nigeria
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Research Interests: computer science, data science, data analytics, ML & AI, information technology
Summary
The growing demand for renewable and carbon-neutral energy systems has accelerated research into advanced electrochemical energy storage technologies. Conventional storage devices often face challenges including low energy density, limited cycling stability, and safety concerns. Emerging quantum materials and two-dimensional nanostructures such as Quantum Dots (QDs), graphene, MXenes, black phosphorus, and Transition Metal Dichalcogenides (TMDs) offer significant potential due to their superior electrical conductivity, tunable electronic properties, and enhanced ion transport capabilities.
This Special Issue, "Emerging Quantum Functional Architectures for Sustainable Energy Storage Devices," focuses on innovative materials, scalable fabrication methods, interface engineering, hybrid nanostructures, and sustainable energy storage architectures for next-generation batteries and supercapacitors. The issue welcomes interdisciplinary contributions related to electrochemistry, nanotechnology, materials science, computational modeling, and renewable-energy integration aimed at improving device performance, stability, safety, and sustainability.
Topics of interest include, but are not limited to:
· Quantum nanomaterials for electrochemical energy storage.
· Two-dimensional materials for sustainable batteries.
· MXene and graphene-based storage architectures.
· Hybrid nanostructures for enhanced charge transport.
· Interface engineering in energy storage systems.
· Biomass-derived materials for sustainable storage.
· Flexible and wearable energy storage devices.
· AI-assisted optimization of storage architectures.
Keywords
quantum materials, sustainable energy storage, electrochemical energy systems. two-dimensional nanomaterials, quantum functional architectures, advanced battery technologies
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