Dr. Mubasher | Condensed Matter Physics | Best Researcher Award

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Dr. Mubasher | Condensed Matter Physics | Best Researcher Award

Assistant Professor | IQRA University | Pakistan

Dr. Mubasher is an accomplished researcher whose scholarly foundation is deeply rooted in Condensed Matter Physics, demonstrating sustained contributions across material synthesis, nanostructure development, and energy-related applications. His body of work reflects a rigorous command of Condensed Matter Physics, particularly in the modification and enhancement of electrode materials, nanohybrids, ferrite systems, graphene derivatives, and multi-walled carbon nanotube composites. With an outstanding record of more than thirty international publications in reputable journals, his research in Condensed Matter Physics exhibits strong emphasis on advanced functional materials and experimental analysis involving impedance spectroscopy, dielectric behavior, cyclic voltammetry, and supercapacitive performance. His professional career represents both academic depth and laboratory capability, further sustained by collaborative research involving interdisciplinary interfaces within Condensed Matter Physics. As an Assistant Professor, his ongoing efforts are directed toward supervising postgraduate and doctoral candidates, enriching the academic environment through applied research in Condensed Matter Physics. His supervision and co-supervision of multiple thesis projects underline a dedication to knowledge transfer, research mentoring, and strengthening the scientific community. His contributions to Condensed Matter Physics extend into peer-review activity for high-impact journals, section editorial work, and involvement in advanced material development with direct relevance to lithium-ion storage and emerging electrochemical technologies. Extensive involvement in composites, doped systems, and material optimization further highlights his innovative approach toward energy-oriented Condensed Matter Physics research. Dr. Mubasher continues to advance the scientific landscape through impactful publications, collaborative research culture, multi-disciplinary integration, and sustained commitment to the global progression of Condensed Matter Physics, reflecting both intellectual maturity and research leadership. His portfolio stands as a remarkable example of academic excellence in the evolving domain of Condensed Matter Physics. Google Scholar profile of 412 Citations, 11 h-index, 12 i10-index.

Profiles: Google Scholar | ORCID

Featured Publications

1. Mujahid, M., Khan, R. U., Mumtaz, M., Soomro, S. A., & Ullah, S. (2019). NiFe₂O₄ nanoparticles/MWCNTs nanohybrid as anode material for lithium-ion battery. Ceramics International, 45(7), 8486–8493.

2. Mubasher, Mumtaz, M., Hassan, M., Ali, L., Ahmad, Z., Imtiaz, M. A., & Aamir, M. F. (2020). Comparative study of frequency-dependent dielectric properties of ferrites MFe₂O₄ (M = Co, Mg, Cr and Mn) nanoparticles. Applied Physics A, 126(5), 334.

3. Mumtaz, M. (2021). Nanocomposites of multi-walled carbon nanotubes/cobalt ferrite nanoparticles: Synthesis, structural, dielectric and impedance spectroscopy. Journal of Alloys and Compounds, 866, 158750.

4. Mumtaz, M., Hassan, M., Ullah, S., & Ahmad, Z. (2021). Nanohybrids of multi-walled carbon nanotubes and cobalt ferrite nanoparticles: High performance anode material for lithium-ion batteries. Carbon, 171, 179–187.

5. Mubasher, Mumtaz, M., & Ali, M. (2021). Structural, dielectric and electric modulus studies of MnFe₂O₄/(MWCNTs)x nanocomposites. Journal of Materials Engineering and Performance, 30(6), 4494–4503.

Dr. Meri Algarni | Condensed Matter Physics | Best Researcher Award

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Dr. Meri Algarni | Condensed Matter Physics | Best Researcher Award

Associate Professor | Al-Baha University | Saudi Arabia

Dr. Meri Algarni is an accomplished researcher in Condensed Matter Physics, recognized for her innovative work on magnetic and topological phenomena in low-dimensional materials. Her contributions have significantly advanced the understanding of electronic and magnetic properties in van der Waals heterostructures, bridging theoretical insights with experimental discoveries in Condensed Matter Physics. With a strong research background in Condensed Matter Physics, she has explored carrier-mediated ferromagnetism, gate-controlled phase transitions, and quantum effects that underpin next-generation spintronic and energy-efficient devices. Dr. Algarni’s expertise in Condensed Matter Physics encompasses nanoscale characterization techniques such as SEM, AFM, and PPMS, enabling her to investigate magnetic and structural behaviors at the atomic scale. Her research in Condensed Matter Physics has been published in high-impact journals, including Physical Review Letters, Nature Communications, and ACS Nano Letters, reflecting global recognition of her scientific contributions. Through her work on tunable artificial topological Hall effects and gate-tuned magnetic transitions, she continues to make influential contributions to Condensed Matter Physics, advancing the development of future quantum materials and low-energy electronic technologies. In addition to her research achievements, Dr. Algarni has actively participated in international conferences and collaborations, strengthening global scientific networks within Condensed Matter Physics. Her dedication to advancing Condensed Matter Physics extends to mentoring and teaching, inspiring emerging scientists to engage in experimental and theoretical studies within the field. Her scholarly impact in Condensed Matter Physics demonstrates a rare combination of technical mastery, analytical rigor, and interdisciplinary insight that drives innovation in material science and nanotechnology. Her Google Scholar profile records 530 citations, an h-index of 11, and an i10-index of 12, underscoring her substantial and growing influence in Condensed Matter Physics worldwide.

Profiles: Google Scholar | ORCID

Featured Publications

1. Zheng, G., Xie, W. Q., Albarakati, S., Algarni, M., Tan, C., Wang, Y., Peng, J., … (2020). Gate-tuned interlayer coupling in van der Waals ferromagnet nanoflakes. Physical Review Letters, 125(4), 047202.

2. Tan, C., Xie, W. Q., Zheng, G., Aloufi, N., Albarakati, S., Algarni, M., Li, J., … (2021). Gate-controlled magnetic phase transition in a van der Waals magnet Fe₅GeTe₂. Nano Letters, 21(13), 5599–5605.

3. Albarakati, S., Xie, W. Q., Tan, C., Zheng, G., Algarni, M., Li, J., Partridge, J., … (2022). Electric control of exchange bias effect in FePS₃–Fe₅GeTe₂ van der Waals heterostructures. Nano Letters, 22(15), 6166–6172.

4. Zheng, G., Wang, M., Zhu, X., Tan, C., Wang, J., Albarakati, S., Aloufi, N., … (2021). Tailoring Dzyaloshinskii–Moriya interaction in a transition metal dichalcogenide by dual-intercalation. Nature Communications, 12(1), 3639.

5. Zheng, G., Tan, C., Chen, Z., Wang, M., Zhu, X., Albarakati, S., Algarni, M., … (2023). Electrically controlled superconductor-to-failed insulator transition and giant anomalous Hall effect in kagome metal CsV₃Sb₅ nanoflakes. Nature Communications, 14(1), 678.

Ran Wang | Materials Science | Women Researcher Award

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Ms. Ran Wang | Materials Science | Women Researcher Award

Student at Beijing Institute of Technology, China

Wang Ran is a dedicated master’s student in Materials Science and Engineering at Beijing Institute of Technology. She completed her undergraduate studies at Shandong University. With a keen interest in absorbing materials, she is committed to advancing research in this field. Though at an early stage in her academic journey, she is eager to contribute to scientific advancements. Wang Ran aspires to explore innovative materials with potential applications in energy absorption and electromagnetic shielding. Her passion for scientific discovery drives her ambition to make significant contributions to materials engineering. She is applying for the Women Research Award or Young Scientist Award. 🌟

Professional Profile 

Education & Experience 📚🔍

  • 🎓 Master’s Degree (Ongoing) – Beijing Institute of Technology, Materials Science and Engineering
  • 🎓 Bachelor’s Degree – Shandong University, Materials Science and Engineering

Professional Development 📖🔬

Wang Ran is in the early stages of her academic career, focusing on developing expertise in absorbing materials. She actively engages in coursework, laboratory experiments, and independent research projects to build a strong foundation in material science. Passionate about innovation, she continuously explores the latest advancements in materials engineering. Though she has not yet published any journals or patents, she is eager to collaborate with experts in her field. Her long-term goal is to contribute groundbreaking research that enhances the performance of absorbing materials in practical applications such as stealth technology and electromagnetic interference shielding. 🚀

Research Focus🏗️🔬

Wang Ran’s research interests lie in the field of absorbing materials, a crucial area in materials science that plays a significant role in energy dissipation, stealth technology, and electromagnetic shielding. She is particularly interested in developing new materials that can efficiently absorb electromagnetic waves and reduce interference in electronic devices. By studying the structural and compositional properties of these materials, she aims to optimize their absorption efficiency and enhance their performance in real-world applications. Her research has potential implications in defense, aerospace, and communication industries, where advanced absorbing materials are essential for improving stealth and signal integrity. 📡🛡️

Awards & Honors 🏆🎖️

  • 🌟 Nominee – Women Research Award (2025)
  • 🌟 Nominee – Young Scientist Award (2025)
  • 🎓 Bachelor’s Degree Completion – Shandong University
  • 📖 Master’s Degree Pursuit – Beijing Institute of Technology

Publication Top Notes

  • “Resonantly pumped acousto-optic Q-switched Er:YAG lasers at 1617 and 1645 nm”

    • Authors: R. Wang, Q. Ye, C. Gao
    • Journal: Applied Optics, 2014
    • Citations: 5
    • Summary:
      • Discusses the development of acousto-optic Q-switched Er:YAG lasers emitting at 1617 nm and 1645 nm.
      • The lasers are resonantly pumped, enhancing efficiency.
      • These wavelengths are valuable for medical, LIDAR, and optical communication applications.

  • “Single-frequency operation of a resonantly pumped 1.645μm Er:YAG Q-switched laser”

    • Authors: R. Wang, Q. Ye, Y. Zheng, M. Gao, C. Gao
    • Type: Conference Paper
    • Citations: 13
    • Summary:
      • Focuses on achieving single-frequency operation of an Er:YAG laser at 1645 nm.
      • Uses resonant pumping and a Q-switching technique for better performance.
      • Suitable for high-precision applications such as spectroscopy and atmospheric sensing.

Conclusion

While Wang Ran shows potential in her research field, she currently lacks the extensive academic contributions and professional engagement necessary to compete for a “Best Researcher” or “Women Researcher” award. She would be a more suitable candidate for a “Young Scientist Award” in the future, provided she enhances her publication record, citations, collaborations, and industry engagement.