Dr. Humaira Rashid Khan is a highly accomplished materials scientist whose research excellence in energy storage, nanomaterials, and photoelectrochemical systems strongly aligns with the expectations of the Best Researcher Award. Her work spans advanced polymer electrolyte membranes, Li–air battery challenges, supercapacitor development, nanocomposite engineering, and ZnO-based photoanodes for solar-driven water splitting, demonstrating both depth and multidisciplinary impact. She has produced significant contributions as evidenced by her 118 Scopus citations, 4 Scopus-indexed documents, and an h-index of 3, while her broader scholarly footprint includes more than 25 peer-reviewed publications in high-impact Q1 and Q2 journals, book chapters with Springer and Elsevier, and major review articles framing the future of next-generation electrochemical devices. Her publications address critical bottlenecks in battery chemistries, propose innovative membrane-fabrication strategies, and report enhanced photocurrent densities through rational nanostructure engineering, reflecting both originality and practical relevance. Dr. Khan has consistently advanced the scientific understanding of charge-transfer mechanisms, thin-film fabrication, dopant-driven band-gap tuning, and nanostructured electrode performance, supporting the global transition toward clean and sustainable energy technologies. Her international postdoctoral research experience, collaborative projects, and contributions to device-level prototypes highlight her ability to translate complex materials science concepts into scalable solutions. Through her rigorous experimentation, mastery of electrochemical and spectroscopic techniques, and sustained high-quality publication record, Dr. Khan demonstrates the research leadership, innovation, and scholarly influence that make her highly suitable for recognition under the Best Researcher Award category.
Featured Publications
Khan, H. R., & Ahmad, A. L. (2025). Supercapacitors: Overcoming current limitations and charting the course for next-generation energy storage. Journal of Industrial and Engineering Chemistry, 141, 46–66. Cited by 149
Khan, H. R., & Ahmad, A. L. (2025). Vapor induced phase separation approach for fabricating high-performance PVDF-HFP/PEO polymer electrolyte membranes with improved electrochemical properties. Materials Today Communications, 42, 111330. Cited by 6
Shuja, F. S. A., Khan, H. R., Murtaza, I., Ashraf, S., & Yousra, … (2024). Supercapacitors for energy storage applications: Materials, devices and future directions: A comprehensive review. Journal of Alloys and Compounds. Cited by 89
Khan, M. S., Murtaza, I., Shuja, A., Fahad, S., Khan, M. W., Ahmmad, J., … Khan, H. R. (2024). Energy on-the-go: V2O5-pBOA-Graphene nanocomposite for wearable supercapacitor applications. Electrochimica Acta, 486, 144119. Cited by 14
Muhammad Shahid Khan, A. N., Murtaza, I., Shuja, A., & Khan, H. R. (2024). Tailored NiO-pBOA-GNP ternary nanocomposite: Advances in flexible supercapacitors and practical applications for wearable technology and environmental monitoring. Journal of Energy Storage, 86, 111128. Cited by 17