Innovative Research Award
| Jianwei Wang | |
|---|---|
| Affiliation | Yan’an University |
| Country | China |
| Scopus ID | 57196393567 |
| Documents | 28 |
| Citations | 1,318 |
| h-index | 18 |
| Subject Area | Chemical Engineering |
| Event | International Academic Achievements & Awards |
| ORCID | 0000-0003-3754-0150 |
Jianwei Wang
Institution: Yan’an University, China
The Innovative Research Award recognizes distinguished scholarly achievement and sustained scientific contributions in Chemical Engineering and advanced energy-storage materials. Jianwei Wang of Yan’an University has established a notable research profile through investigations into aqueous zinc-ion batteries, rare-earth functional materials, electrochemical energy storage, and advanced nanostructured electrode engineering. His scholarly publications demonstrate continued contributions toward improving battery performance, structural stability, and electrochemical efficiency while advancing sustainable energy technologies.[1]
Abstract
Jianwei Wang’s research emphasizes the design of high-performance electrochemical energy-storage materials through nanostructure engineering, rare-earth modification, multifunctional carbon composites, and electrode optimization. His work contributes to enhancing capacity retention, cycling durability, charge-transfer kinetics, and structural stability of aqueous zinc-ion batteries. The published studies demonstrate practical approaches toward next-generation sustainable energy systems while strengthening the scientific understanding of electrochemical mechanisms.[2]
Keywords
Chemical Engineering, Aqueous Zinc-Ion Batteries, Rare Earth Materials, Electrochemical Energy Storage, Nanomaterials, Battery Cathodes, Electrode Engineering
Introduction
Modern electrochemical energy storage requires electrode materials capable of delivering long cycle life, high energy density, rapid ion transport, and structural durability. Jianwei Wang’s investigations address these scientific challenges through advanced material synthesis, morphology regulation, composite engineering, and rare-earth-assisted stabilization strategies. His publications contribute to the broader field of sustainable battery technologies by integrating materials science with electrochemical engineering principles.[3]
Research Profile
- Primary discipline: Chemical Engineering.
- Research emphasis on aqueous zinc-ion battery technologies.
- Development of nanostructured cathode materials.
- Rare-earth functional materials for electrochemical stability.
- Composite electrode design and multifunctional carbon materials.
- Published 28 indexed scholarly documents with significant citation impact.
Research Contributions
The research portfolio includes investigations into charge reconstruction mechanisms, nanomaterial activation, morphology modification, multifunctional carbon composites, and rare-earth pillar engineering. These studies collectively improve electrochemical reversibility, cycling stability, conductivity, and ion diffusion while advancing practical battery applications.[4]
Publications
- Charge reconstruction via yttrium/polyaniline co-intercalation in yolk-shell cathode enables ultrafast and stable aqueous zinc-ion storage. Journal of Rare Earths (2026). DOI: 10.1016/j.jre.2026.01.022
- A facile morphologic modification strategy enabling robust resistive switching and electrochemical behavior of MnO2. Chemical Engineering Journal (2025). DOI: 10.1016/j.cej.2025.161672
- Dual modulation of homogeneous nanomaterialization and electrochemical activation enhancing zinc ion storage. Science China Chemistry (2025). DOI: 10.1007/s11426-024-2166-7
- Pitch-derived multifunctional carbon and bimetallic sulfide composite electrodes for aqueous energy storage. Journal of Alloys and Compounds (2025). DOI: 10.1016/j.jallcom.2024.177957
- Rare earth pillars for stable layered birnessite cathodes propelling aqueous zinc-ion batteries with ultra-long cyclability. Inorganic Chemistry Frontiers (2025). DOI: 10.1039/D4QI02654C
Research Impact
According to the supplied scholarly metrics, Jianwei Wang has authored 28 Scopus-indexed publications that have accumulated more than 1,300 citations, resulting in an h-index of 18. These indicators reflect consistent scholarly influence within electrochemical energy storage, materials engineering, and chemical engineering research communities.[1]
Award Suitability
The Innovative Research Award recognizes originality, scientific rigor, measurable scholarly impact, and sustained research excellence. Jianwei Wang’s publication record, citation profile, and contributions to advanced battery technologies demonstrate alignment with these evaluation principles through high-quality peer-reviewed research, innovation in material design, and advancement of electrochemical engineering knowledge.[5]
Conclusion
Jianwei Wang has established an active research profile in Chemical Engineering through significant contributions to aqueous zinc-ion battery technology, nanostructured electrode materials, and rare-earth-assisted electrochemical systems. His scholarly productivity, research quality, and measurable scientific influence support recognition within international academic award programs focused on innovation and research excellence.
External Links
References
- Elsevier. (n.d.). Scopus author details: Jianwei Wang, Author ID 57196393567. Scopus.
https://www.scopus.com/authid/detail.uri?authorId=57196393567 - Wang, J. et al. (2026). Charge reconstruction via yttrium/polyaniline co-intercalation in yolk-shell cathode enables ultrafast and stable aqueous zinc-ion storage. Journal of Rare Earths.
https://doi.org/10.1016/j.jre.2026.01.022 - Wang, J. et al. (2025). A facile morphologic modification strategy enabling robust resistive switching and electrochemical behavior of MnO2. Chemical Engineering Journal.
https://doi.org/10.1016/j.cej.2025.161672 - Wang, J. et al. (2025). Dual modulation of homogeneous nanomaterialization and electrochemical activation enhancing zinc ion storage. Science China Chemistry.
https://doi.org/10.1007/s11426-024-2166-7