Innovative Research Award
| Muhammad Yousif | |
|---|---|
| Affiliation | Qinghai Institute of Saltlakes Chinese Academy of Sciences |
| Country | China |
| Scopus ID | 57211409200 |
| Documents | 19 |
| Citations | 156 |
| h-index | 7 |
| Subject Area | Materials Science |
| Event | International Academic Achievements & Awards |
| ORCID | 0000-0002-9151-0748 |
Muhammad Yousif
Institution: Qinghai Institute of Saltlakes Chinese Academy of Sciences, China
Muhammad Yousif is a researcher in the field of Materials Science, with scholarly contributions focused on advanced functional materials, nanotechnology, wearable sensing systems, environmental remediation, and smart textile engineering. His research integrates interdisciplinary approaches involving nanocomposites, graphene-derived materials, hydrogel-based sensing platforms, and textile-based electronic devices to address scientific and engineering challenges in environmental sustainability and intelligent materials development.[1]
Abstract
Muhammad Yousif has established a research profile centered on advanced materials engineering with applications in environmental treatment, smart sensing technologies, and wearable electronics. His publications demonstrate continued investigation into graphene-based nanomaterials, textile-integrated sensors, hydrogel composites, and functional fibers that contribute to modern materials science. The combination of environmental engineering principles and intelligent material design illustrates an interdisciplinary research approach consistent with emerging international trends in sustainable technology.[1]
Keywords
Materials Science; Nanotechnology; Graphene; Reduced Graphene Oxide; Smart Textiles; Wearable Electronics; Hydrogel Composites; Textile Sensors; Environmental Remediation; Dye Removal; Functional Fibers; Flexible Electronics; Advanced Nanocomposites.
Introduction
Recent developments in materials science increasingly emphasize multifunctional materials capable of simultaneously addressing environmental, biomedical, and electronic applications. Muhammad Yousif’s research contributes to these objectives through investigations into conductive textile architectures, responsive hydrogel systems, nanocomposite catalysts, and environmentally sustainable adsorption technologies. His scholarly work demonstrates the integration of chemistry, materials engineering, textile science, and sensor technology into practical engineering solutions.[2]
Research Profile
The research profile of Muhammad Yousif encompasses the design, synthesis, characterization, and application of advanced functional materials. His Scopus record reports 19 indexed publications, 156 citations, and an h-index of 7, reflecting consistent scholarly activity within the international materials science community.[1]
- Wearable and flexible sensing systems
- Graphene-based nanocomposites
- Environmental wastewater remediation
- Hydrogel-textile multifunctional materials
- Fiber-based intelligent sensing technologies
Research Contributions
Among his recent contributions are studies describing aramid nanofiber adsorption systems for dye recovery, reduced graphene oxide hybrid yarn sensors for wearable devices, braided optical fiber sensing technologies, hydrogel-textile multimodal sensing platforms, and nanocomposite catalysts for degradation of organic pollutants. These investigations contribute to the advancement of sustainable materials, flexible electronics, and environmental technologies.[2][3][4]
Publications
- Efficient, reversible recovery of anionic acidic dyes from water with aramid nanofibers. The Journal of The Textile Institute (2026). DOI:
10.1080/00405000.2026.2670988 - Scalable rGO–Ni Hybrid Yarn Sensors for Durable and Sensitive Wearable Electronics. IEEE Sensors Journal (2026). DOI:
10.1109/JSEN.2026.3654231 - Fiber Braiding Structure for Spatially Resolved Intensity-Modulated Liquid Level Sensing. IEEE Sensors Journal (2026). DOI:
10.1109/JSEN.2026.3704258 - A hydrogel–textile composite with synapse-inspired ionic multimodal sensing. Science China Materials (2025). DOI:
10.1007/s40843-025-3644-9 - High-performance catalytic degradation of rhodamine 6G dye by NiO/Reduced graphene oxide nanocomposite from the wastewater system. International Journal of Environmental Analytical Chemistry (2025). DOI:
10.1080/03067319.2025.2532590
Research Impact
The published research has contributed to the advancement of environmentally sustainable nanomaterials, multifunctional sensing platforms, and flexible wearable systems. The citation profile indicates measurable scholarly recognition within materials science, particularly in emerging topics involving smart textiles, graphene-enabled devices, and environmental remediation technologies.[1]
Award Suitability
Based on documented publication output, interdisciplinary research scope, measurable citation performance, and continued contributions to advanced materials science, Muhammad Yousif demonstrates characteristics commonly associated with recognition under an Innovative Research Award. His work addresses practical scientific challenges through the development of advanced materials for environmental protection, sensing technologies, and wearable electronics while maintaining consistent scholarly productivity.[1]
Conclusion
Muhammad Yousif’s academic portfolio illustrates sustained contributions to materials science through innovative research involving nanomaterials, smart textiles, hydrogel composites, and environmental technologies. His publication record, citation performance, and interdisciplinary investigations collectively support his standing as an active researcher contributing to contemporary developments in advanced functional materials.
External Links
References
- Elsevier. (n.d.). Scopus Author Details: Muhammad Yousif, Author ID 57211409200.
https://www.scopus.com/authid/detail.uri?authorId=57211409200 - Yousif, M. et al. (2026). Efficient, reversible recovery of anionic acidic dyes from water with aramid nanofibers. The Journal of The Textile Institute.
DOI:
https://doi.org/10.1080/00405000.2026.2670988 - Yousif, M. et al. (2026). Scalable rGO–Ni Hybrid Yarn Sensors for Durable and Sensitive Wearable Electronics. IEEE Sensors Journal.
DOI:
https://doi.org/10.1109/JSEN.2026.3654231 - Yousif, M. et al. (2026). Fiber Braiding Structure for Spatially Resolved Intensity-Modulated Liquid Level Sensing. IEEE Sensors Journal.
DOI:
https://doi.org/10.1109/JSEN.2026.3704258 - Yousif, M. et al. (2025). A hydrogel–textile composite with synapse-inspired ionic multimodal sensing. Science China Materials.
DOI:
https://doi.org/10.1007/s40843-025-3644-9