Wenjie Ren | Nanocomposites | Best Researcher Award

Published on 31/10/202531/10/2025 by Nano Technology

Dr. Wenjie Ren | Nanocomposites | Best Researcher Award

Doctor of Philosophy (Ph.D) | Henan University of Technology | China

Dr. Wenjie Ren, Ph.D., is an accomplished researcher at Henan University of Technology, China, specializing in immunological detection technologies and genetic engineering antibodies. Her research primarily focuses on developing rapid and highly sensitive biosensing systems for small molecule detection, integrating nanotechnology and immunoassay innovations to address challenges in food safety and environmental monitoring. With 1,007 citations, 67 research publications, and an h-index of 18, Dr. Wenjie Ren has established a strong scientific footprint in fields such as nanomaterial synthesis, immunochromatography, fluorescence sensing, and bioluminescent enzyme immunoassays. She has successfully led nine major research projects, including one funded by the National Natural Science Foundation of China (Youth Program) and several provincial and collaborative initiatives. Her representative works include the development of nanobody-based CuS nanoflower–Au lateral flow immunoassay strips and DNA tetrahedron fluorescence sensors for simultaneous detection of food contaminants such as aflatoxin B1 and ochratoxin A. These innovations have advanced analytical performance, sensitivity, and field applicability in food and agricultural testing. Dr. Wenjie Ren holds three authorized patents in nanobody-based and dual-signal amplification immunochromatography technologies. Her research excellence has been recognized through First and Second Prizes in the Henan Provincial Science and Technology Achievement and Progress Awards, particularly for pioneering functionalized nanocomposite biosensors. Beyond her publications and patents, she contributes as a research supervisor, fostering young scientific talent in molecular detection and biosensor design. Her interdisciplinary approach bridges immunochemistry, nanotechnology, and analytical biochemistry, positioning her as a key contributor to next-generation diagnostic sensor research and its translational applications in food safety and biomedical fields.

Profiles: Scopus | ResearchGate | Sci Profiles | Scilit | Scholar GPS

Featured Publications

Zhao, Y., He, B., & Ren, W. (2024). Nanobody and CuS nanoflower-Au-based lateral flow immunoassay strip to enhance the detection of aflatoxin B1. Foods, 13(12), 1845.
Li, Y., Li, Z., Jia, B., & Ren, W. (2024). Detection of AFB1 by immunochromatographic test strips based on double-probe signal amplification with nanobody and biotin–streptavidin system. Foods, 13(21), 3396.
Pang, J., Ren, W., He, B., et al. (2023). Development of a rapid gold nanoflowers immunochromatographic test strip based on the nanobody for detection of aflatoxin B1. ChemistrySelect, 8(40), e202300913.
Ren, W., Pang, J., Ma, R., et al. (2022). A signal on–off fluorescence sensor based on the self-assembly DNA tetrahedron for simultaneous detection of ochratoxin A and aflatoxin B1. Analytica Chimica Acta, 1198, 339566.
Ren, W., Xu, Y., Huang, Z., et al. (2020). Single-chain variable fragment antibody-based immunochromatographic strip for rapid detection of fumonisin B1 in maize samples. Food Chemistry, 319, 126546.

Md. Naimur Rahman | Material Science | Best Researcher Award

Published on 30/08/202530/08/2025 by Nano Technology

Mr. Md. Naimur Rahman | Material Science | Best Researcher Award

Graduate Researcher at Khulna University of Engineering and Technology | Bangladesh

Mr. Md. Naimur Rahman is a physics researcher with expertise in smart material systems, biomedical applications, and nanoferrite synthesis. He earned his B.Sc. in Physics from the University of Barishal and an M.Sc. in Physics from Khulna University of Engineering & Technology (KUET), where his dissertation focused on cobalt-doped manganese-based nanoferrites for biomedical use. Alongside his research, he has teaching and lab experience at KUET and has published in reputed journals, demonstrating both academic excellence and resilience in overcoming resource-limited research environments.

Professional Profile

Scopus Profile

Google Scholar Profile

Orcid Profile

Education

Mr. Md. Naimur Rahman completed his Bachelor of Science degree in Physics at the University of Barishal, Bangladesh, where he gained a strong foundation in core physics principles. He then pursued a Master of Science degree in Physics at the Solid State Physics Laboratory, Department of Physics, Khulna University of Engineering & Technology (KUET), Bangladesh. Under the supervision of Dr. Md. Alamgir Hossain, he carried out his dissertation on “Synthesis of Cobalt-doped Manganese-based Nano-ferrite Through Chemical Co-precipitation Method for Biomedical Applications”. His academic journey reflects both strong theoretical grounding and practical research expertise in the field of materials science and physics.

Experience

Mr. Md. Naimur Rahman has gained valuable academic and research experience through his role as a Teaching Assistant in the Physics Department at Khulna University of Engineering & Technology (KUET). In this position, he provided instructional support in introductory physics laboratory courses across several engineering departments, helping students develop practical skills and strengthening his own teaching and mentoring abilities. Alongside his teaching duties, he has actively engaged in research, overcoming the limitations of material science research facilities in his country by focusing on detailed data analysis, effective collaboration with peers, and the publication of high-quality scientific papers. His hands-on work in synthesizing cobalt-doped manganese-based nanoferrites for biomedical applications, coupled with his contributions to collaborative projects, highlights his resilience, adaptability, and growing expertise in materials science and applied physics.

Research Interests

Mr. Md. Naimur Rahman’s research interests lie in the design and development of advanced functional materials with applications across multiple scientific and technological domains. He is particularly focused on smart material systems and stimuli-responsive materials, with potential uses in biomedical engineering, bioprinting, and healthcare. His interests also extend to aerospace and deployable structures, electronics with functional integration, and the development of sustainable and circular manufacturing approaches. He is keen on exploring AI-driven additive manufacturing, textile and wearable technologies, as well as process hybridization and scale-up methods. Through this interdisciplinary focus, he aims to contribute to innovative solutions that address global challenges in science, technology, and sustainability.

Publications

Investigation of annealing temperature effect on structural, morphological, optical, magnetic, and dielectric properties of cobalt-doped manganese ferrites

Cited: 8

Effect of annealing on the structural, morphological, optical, magnetic, and dielectric properties of nickel-doped cobalt nanoferrites for electronic applications

Cited: 3

Investigation of calcination temperature effect on crystallographic, morphological, optical, and magnetic properties of silver-doped magnesium ferrite nanoparticles

Cited: 2

Enhanced superparamagnetism and polarizability via reverse annealing in Mg-doped Co-ferrite: structural, morphological, and optical investigations for biomedical applications

Cited: 1

Conclusion

Mr. Md. Naimur Rahman is a highly suitable candidate for the Research for Best Researcher Award, given his strong academic record, research resilience, and contributions to advanced material systems despite limited resources. His dedication, adaptability, and innovative approach position him as a rising talent with significant potential for future breakthroughs. With expanded international collaborations, deeper experimental engagement, and increased dissemination of his research outcomes, Mr. Rahman is poised to make impactful contributions to physics, materials science, and interdisciplinary innovation.

Prachi Jain | Nanocomposites | Best Researcher Award

Published on 04/07/202504/07/2025 by Nano Technology

Dr. Prachi Jain | Nanocomposites | Best Researcher Award

Senior Researcher at Netaji Subhas University of Technology, India

Dr. Prachi Jain is a Ph.D. candidate in Physics with a specialization in Materials Science at Netaji Subhas University of Technology (NSUT), Delhi, India, Her doctoral research focuses on the development of rare-earth and transition metal co-substituted spinel ferrites for hydroelectric cell applications, emphasizing green energy generation and enhanced oxygen evolution reactions. Dr. Jain holds an M.Sc. in Physics from the Central University of Punjab and a B.Sc. (Hons.) in Physics from the University of Delhi. She has presented her work at multiple international conferences, including ICMDA-Japan and RAFM-India, and is skilled in nanomaterials synthesis, thin film fabrication, and advanced material characterization techniques. Her interdisciplinary expertise spans dielectric studies, magnetic properties, and electrochemical energy storage systems.

Professional Profile:

SCOPUS

GOOGLE SCHOLAR

ORCID

Summary of Suitability for Best Researcher Award

Dr. Prachi Jain is a promising materials physicist with a strong focus on energy harvesting, multiferroics, and hydroelectric cell technologies, demonstrating a rare combination of experimental expertise, device-level application, and deep material characterization skills. Her Ph.D. research investigates rare-earth and transition metal co-substituted spinel ferrites, pioneering their use in cost-effective green energy generation via hydroelectric cells.

🎓 Education

📚 Ph.D. in Physics (Materials Science)
Netaji Subhas University of Technology, Delhi
🔬 Thesis: Rare-Earth and Transitional Metal Co-Substituted Spinel Ferrites for Hydroelectric Cell Device Applications

📘 M.Sc. in Physics
Central University of Punjab, India
🧪 Thesis: Synthesis and Characterization of Fluorescent Carbon Dots
📊 CGPA: 7.76

🎓 B.Sc. (Hons.) in Physics
Shivaji College, University of Delhi
📊 CGPA: 8.3

🧪 Research Interests & Expertise

💧 Hydroelectric Cell Development

⚛️ Multiferroics, Spinel Ferrites, and Co-Doped Metal Oxides

🔬 Wet-Chemical Synthesis: Sol-Gel, Hydrothermal, Co-Precipitation

🧫 Thin Film Preparation: PVD, CVD

🧠 Advanced Characterization: XRD, FESEM, TEM, FTIR, VSM, UV-DRS, CV

📈 Simulation Tools: FULLPROF, VESTA, ZSimpWin, EISSA, Origin, ImageJ

🧠 Ongoing Research Work

⚡ LaCoO₃: Temperature-dependent structural & magnetic studies for energy storage

🧲 Cu-doped YCrO₃: Dielectric & impedance investigation

💧 Mn-substituted oxides: Green energy via hydroelectric cells

🌿 SrFe₂O₄: Eco-friendly nanoparticles for supercapacitor applications

🏆 Achievements & Presentations

🎤 International/ National Conference Presentations:

🇯🇵 ICMDA-2023, Chiba University, Japan

🇮🇳 RAFM-2022 & RAFM-2024, University of Delhi

🇮🇳 ICAMET-2023, NSUT

🇮🇳 AFMD-2025, University of Delhi

🇮🇳 IC-STAR, VIT Bhopal

🌍 28th Intl. Conf. on Nuclear Tracks and Radiation Measurements

📚Publication Top Notes

Unveiling the impact of Ni 2+/Y 3+ co-substitution on the structural, dielectric, and impedance properties of multiferroic spinel ferrite for hydroelectric cell application

Cited : 26

Exploring the multiferroic and water sensing behavior of Cu/Er co-substituted ferrites as key enablers for next-gen hydroelectric cells

Cited : 9

Advancements in multiferroic, dielectric, and impedance properties of copper–yttrium co-doped cobalt ferrite for hydroelectric cell applications

Cited : 7

Al³⁺-substituted magnesium ferrites (MgAlₓFe2-xO4) for advanced hydroelectric cells and pseudocapacitors: Insights into the structural, morphological, and electrical studies

Cited : 6

Investigation of Mg²⁺ Ion Substitution on the Structural, Electric, and Magnetic Properties of Soft Spinel Ferrites (NiFe₂O₄) for High-Frequency Applications

Cited : 5

Shivam Srivastava | Material Science | Young Scientist Award

Published on 25/03/202525/03/2025 by Nano Technology

Mr. Shivam Srivastava | Material Science | Young Scientist Award

Research scholor at Dr Shakuntala Misra National Rehabilitation University Lucknow, India.

🔬 Shivam Srivastava is a dedicated researcher specializing in Material Science, currently pursuing a Ph.D. in Physics at Dr. Shakuntala Misra National Rehabilitation University, Lucknow (Thesis submission in progress). With an M.Sc. in Physics from Lucknow University (2021, 79%) and a B.Sc. in PCM from CSJM University, Kanpur (2019, 64%), he has built a strong academic foundation. His research focuses on thermoelastic properties, high-pressure analysis, and nanomaterials, with several publications in reputed journals. Proficient in XRD, SEM, FTIR, and computational tools, he actively contributes to advancing materials science.

Professional Profile:

Scopus

Suitability for Young Scientist Award – Shivam Srivastava

Shivam Srivastava is an emerging researcher in Material Science, making significant contributions to thermoelastic properties, high-pressure analysis, and nanomaterials. His expertise in computational modeling and experimental techniques such as XRD, SEM, and FTIR strengthens his research. His publications in reputed journals, coupled with active participation in national and international conferences, demonstrate his commitment to advancing material science. With a strong academic background, technical skills, and innovative research, he is a promising candidate for the Young Scientist Award.

Education & Experience

📚 Education:

🎓 Ph.D. in Physics – Dr. Shakuntala Misra National Rehabilitation University, Lucknow (Thesis Submitted)
🎓 M.Sc. in Physics – Lucknow University (2021, 79%)
🎓 B.Sc. in PCM – CSJM University, Kanpur (2019, 64%)
🏫 12th (PCM, Hindi, English) – UP Board (2016, 96%)
🏫 10th (Science, Math, Computer, Hindi, English) – UP Board (2014, 86%)

🛠 Technical Experience:

🏗 Experimental Techniques: XRD, SEM, FTIR, EDS
💻 Software Proficiency: Gaussian, BURAI, Origin, MS Office
🌎 Languages Known: English, Hindi

Professional Development

📖 Shivam Srivastava actively engages in computational modeling and experimental research in material science. His expertise spans thermoelastic properties, high-pressure behavior, and nanomaterials, contributing significantly to energy storage and industrial applications. He has published multiple high-impact research papers, focusing on carbon nanotubes, lithium-ion battery materials, and molecular crystals. He stays updated with advanced computational techniques and regularly participates in national and international research forums. With strong analytical skills and hands-on experience in experimental physics and software simulations, he aims to drive innovative material research for future technological advancements.

Research Focus

🔬 Shivam Srivastava’s research primarily revolves around Material Science, with a specific focus on nanomaterials, elastic properties, and high-pressure studies. His work explores thermoelastic properties of carbon nanotubes, Grüneisen pa

rameter analysis for carbides and bromides, and high-pressure behavior of lithium-based materials used in energy storage. Utilizing equations of state and computational methods, he investigates structural and mechanical properties of materials under extreme conditions. His research aims to enhance the efficiency of energy storage materials, improve mechanical stability in industrial applications, and develop new materials with optimized properties for technological advancements.

Awards & Honors

🏅 Academic Excellence: Consistently ranked among top performers in M.Sc. and B.Sc.
📜 Research Publications: Published in reputed journals with high impact factors.
🏆 Scholarship & Recognition: Recognized for outstanding research contributions in Material Science.
🎤 Conference Participation: Actively presented research at national and international platforms.
💡 Innovation in Research: Contributed to new theoretical models in elastic properties and nanomaterials.

Publication Top Notes

🔬 Dimensional Effect on Phonon Frequency Vibrations of Nanostructured Materials