Tag: Smart Materials Award

Yepin Zhao | Materials Science | Best Researcher Award

Published on by World Science Awards

Best Researcher Award

Yepin Zhao
Stanford University, United States

Yepin Zhao
Affiliation Stanford University
Country United States
Scopus ID 57195035000
Documents 47
Citations 6455
h-index 30
Subject Area Materials Science, Energy Materials, Wearable Electronics
Event World Science Awards

Yepin Zhao is a materials scientist and postdoctoral researcher in the Department of Chemical Engineering at Stanford University. His research spans stretchable electronics, implantable biosensors, perovskite photovoltaics, organic solar cells, thin-film transistors, and advanced energy materials. Through interdisciplinary contributions across materials science, renewable energy technologies, and wearable healthcare systems, Zhao has established a research portfolio focused on developing high-performance, durable, and scalable technologies for future energy and biomedical applications.[1]

Abstract

Yepin Zhao’s academic contributions encompass advanced materials engineering, renewable energy technologies, and bio-integrated electronics. His work has significantly advanced the understanding of perovskite photovoltaics, semitransparent organic solar cells, flexible electronic systems, and stretchable biomedical devices. His research demonstrates a strong emphasis on improving device efficiency, operational stability, environmental sustainability, and translational potential for real-world applications. Through collaborations at Stanford University and UCLA, Zhao has contributed to multiple high-impact publications in leading scientific journals and has participated in several nationally funded research initiatives.[2]

Keywords

Stretchable Electronics, Wearable Sensors, Biointerfaces, Perovskite Solar Cells, Organic Photovoltaics, Thin Film Transistors, Smart Greenhouse Technology, Implantable Electronics, Renewable Energy Materials, Energy Storage Devices, Semiconductor Engineering, Sustainable Technologies.

Introduction

The development of advanced materials capable of addressing challenges in energy sustainability, healthcare monitoring, and electronic device durability remains a central objective of modern materials science. Yepin Zhao’s research career reflects this multidisciplinary objective through investigations into semiconductor materials, photovoltaics, wearable technologies, and implantable systems. His work combines materials chemistry, device engineering, and interface science to improve performance and reliability across multiple technological domains.[3]

Research Profile

Following his Bachelor of Science degree in Materials Physics from Nanjing University and Master of Science degree in Materials Science and Engineering from Carnegie Mellon University, Zhao completed his Ph.D. at UCLA under the supervision of Professor Yang Yang. He subsequently served as a postdoctoral researcher at UCLA before joining Stanford University under the mentorship of Professor Zhenan Bao. His research trajectory has evolved from energy storage materials and thin-film electronics to next-generation stretchable and implantable electronic platforms.[1]

  • Bio-interfaces and implantable sensing systems.
  • Stretchable and wearable electronics.
  • Perovskite and organic photovoltaic technologies.
  • Indium-Gallium-Zinc Oxide thin-film transistors.
  • Energy storage materials and pseudocapacitors.

Research Contributions

Among Zhao’s most influential contributions is the development of stable semitransparent organic photovoltaic systems for greenhouse integration, enabling simultaneous food and energy production. His Nature Sustainability publication demonstrated pathways toward sustainable agricultural infrastructure through photovoltaic-photosynthesis integration.[4]

He has also contributed significantly to understanding defect passivation, ion migration suppression, and interface engineering in perovskite solar cells, resulting in enhanced efficiency and durability of photovoltaic devices. Several of these studies appeared in Nature Materials, Science, Journal of the American Chemical Society, and Advanced Materials.[5]

At Stanford University, Zhao’s work focuses on mechanically robust stretchable electronic systems, advanced polymer encapsulation materials, implantable neural sensors, and mobile health monitoring technologies. These projects support the development of next-generation biomedical devices capable of long-term operation under dynamic physiological conditions.[1]

Publications

  • Achieving Sustainability of Greenhouses by Integrating Stable Semi-Transparent Organic Photovoltaics. Nature Sustainability (2023).
  • Suppressing Ion Migration in Metal Halide Perovskites via Trace of Multivalent Interstitial Doping. Nature Materials (2022).
  • Dual-Functional p-Type Soft Interlayer for Semitransparent Organic Photovoltaics. ACS Nano (2021).
  • Molecular Interaction Regulates Defect Passivation for Perovskite Solar Cells. Journal of the American Chemical Society (2020).
  • A Polymerization-Assisted Grain Growth Strategy for Efficient and Stable Perovskite Solar Cells. Advanced Materials (2020).
  • High Performance IGZO Thin Film Transistors via Interface Engineering. Advanced Functional Materials (2020).
  • Superelastic Pseudocapacitors from Freestanding Graphene-Coated Carbon Nanotube Aerogels. ACS Applied Materials & Interfaces (2017).

Research Impact

Zhao’s publication record includes articles in Nature Sustainability, Nature Materials, Science, Nature Reviews Materials, Advanced Materials, ACS Nano, Joule, Matter, and other leading journals. His work has attracted substantial scholarly attention and contributed to advances in photovoltaics, semiconductor engineering, wearable technologies, and energy materials. He has also served as a reviewer for premier journals including Nature Photonics, Nature Communications, Journal of the American Chemical Society, and Advanced Functional Materials.[3]

Beyond publications, Zhao has contributed to multiple federally funded projects supported by organizations such as the Office of Naval Research, National Science Foundation, Department of Energy, California Energy Commission, and UCLA Technology Development Group. These projects collectively represent several million dollars in competitive research funding and demonstrate leadership in proposal development and project execution.[4]

Award Suitability

Yepin Zhao’s achievements align strongly with recognition in advanced materials science, renewable energy innovation, and wearable electronic systems. His interdisciplinary research has produced impactful scientific discoveries while simultaneously addressing practical challenges in sustainable energy generation, healthcare technologies, and electronic device reliability. His record of high-impact publications, competitive research funding, mentoring activities, and international collaborations supports his suitability for distinguished academic and scientific awards.[2]

Conclusion

Yepin Zhao represents a new generation of interdisciplinary materials scientists whose work bridges energy technologies, electronics, and biomedical engineering. Through sustained contributions to photovoltaic science, stretchable electronics, and advanced materials development, he has established a research portfolio characterized by scientific rigor, technological relevance, and translational potential. His scholarly achievements position him among emerging leaders in materials science and engineering research.[1]

References

  1. Curriculum Vitae of Yepin Zhao. Stanford University and UCLA Academic Record.
  2. Zhao, Y. Academic publication portfolio in materials science, photovoltaics, and stretchable electronics.
  3. Research Projects and Scientific Contributions documented in professional curriculum vitae.
  4. Zhao, Y. et al. (2023). Achieving sustainability of greenhouses by integrating stable semi-transparent organic photovoltaics. Nature Sustainability.
    https://doi.org/10.1038/s41893-023-01086-0
  5. Zhao, Y. et al. (2022). Suppressing Ion Migration in Metal Halide Perovskites via Trace of Multivalent Interstitial Doping. Nature Materials.
    https://doi.org/10.1038/s41563-022-01377-4

Tiange Zhao | Materials Science | Best Researcher Award

Published on by World Science Awards

Best Researcher Award

Tiange Zhao
Shanghai Institute of Technical Physics, Chinese Academy of Sciences, Shanghai, China
Tiange Zhao
Affiliation Shanghai Institute of Technical Physics, Chinese Academy of Sciences
Country China
Scopus ID 57825529200
Documents 17
Citations 462
h-index 9
Subject Area Materials Science, Optoelectronics, Infrared Photodetection, Two-Dimensional Materials
Event World Science Awards

Tiange Zhao is a Chinese materials scientist and postdoctoral researcher affiliated with the Shanghai Institute of Technical Physics, Chinese Academy of Sciences. His research activities are primarily centered on the controllable synthesis of narrow-band two-dimensional materials and the development of high-performance infrared photodetection devices. Zhao has contributed to the advancement of wafer-scale two-dimensional material growth, substrate engineering strategies, and topological insulator-based photodetectors for broadband and mid-wave infrared applications.[1]

Abstract

Tiange Zhao has developed a scholarly profile in the field of materials physics and optoelectronic engineering through research on two-dimensional materials and infrared photodetection technologies. His work addresses challenges associated with wafer-scale synthesis, substrate engineering, and heterojunction integration for advanced optoelectronic systems. Zhao’s publications in internationally recognized journals indicate active contributions to next-generation infrared sensing technologies and scalable material fabrication approaches.[2]

Keywords

  • Two-dimensional materials
  • Infrared photodetection
  • Topological insulators
  • Wafer-scale synthesis
  • Materials science and engineering
  • Optoelectronic devices
  • Bi2Se3 heterojunctions
  • Broadband photodetectors

Introduction

Research in two-dimensional materials has become increasingly important for the advancement of modern optoelectronic systems, particularly in infrared sensing and high-speed photodetection applications. Tiange Zhao’s academic work contributes to this rapidly evolving field through the synthesis, transfer, and integration of narrow-band materials designed for scalable device fabrication. His research integrates material science principles with device engineering strategies to improve infrared response performance, reduce dark current limitations, and enhance large-scale manufacturability.[3]

Research Profile

Tiange Zhao completed his Bachelor of Science degree in Materials Science and Engineering at Zhengzhou University between 2010 and 2014. He subsequently earned a Master of Science degree in the same discipline from Zhengzhou University during 2015–2018. Zhao later pursued doctoral research in Materials Physics and Chemistry at Sun Yat-sen University from 2019 to 2023.[1]

Since 2023, Zhao has served as a postdoctoral researcher at the Shanghai Institute of Technical Physics, Chinese Academy of Sciences, under the supervision of Professor Weida Hu. His academic specialization encompasses controllable synthesis methods for narrow-band two-dimensional materials and the development of high-performance infrared photodetection mechanisms and devices.[2]

Research Contributions

Zhao’s research contributions include advancements in wafer-scale transfer techniques for two-dimensional materials and substrate engineering methodologies for scalable material growth. His work has explored epitaxial growth strategies for topological insulator materials such as Bi2Se3 and the fabrication of heterojunction structures capable of achieving ultrabroadband infrared responses.[4]

He has also contributed to the development of low dark-current infrared photodetectors and broadband photodetection systems based on Bi2O2Te nanosheets. These investigations support the broader scientific objective of improving optoelectronic device efficiency, scalability, and operational stability in practical sensing applications.[5]

  • Development of wafer-scale transfer techniques for two-dimensional materials
  • Research on substrate engineering strategies for scalable synthesis
  • Investigation of topological insulator-based infrared photodetectors
  • Optimization of low dark-current heterojunction systems
  • Broadband optoelectronic device fabrication and characterization

Publications

Tiange Zhao has authored and coauthored multiple peer-reviewed scientific articles in journals focused on materials science, nanotechnology, and optoelectronics. Selected representative publications are listed below.

  1. Zhao, T., et al. “Wafer-scale transfer of two-dimensional materials with UV tape.” Nature Electronics, 2024, 7, 96–97.
    DOI: https://doi.org/10.1038/s41928-023-01076-6
  2. Zhao, T., et al. “Substrate Engineering for Wafer-scale Two-dimensional Material Growth: Strategies, Mechanisms, and Perspectives.” Chemical Society Reviews, 2023, 52, 1650–1671.
    DOI: https://doi.org/10.1039/D2CS00793A
  3. Zhao, T., et al. “Edge-Dominated Epitaxy of Topological Insulator Bi2Se3 with Ultrabroadband Response.” ACS Nano, 2025, 19, 26055–26064.
  4. Zhao, T., et al. “Topological insulator Bi2Se3 heterojunction with a low dark current for mid-wave infrared photodetection.” ACS Photonics, 2024, 11(6), 2450–2458.
    DOI: https://doi.org/10.1021/acsphotonics.4c00219
  5. Duan, S., Zhao, T.*, et al. “Controlled Synthesis of Bi2O2Te Nanosheets for High-Performance Broadband Photodetectors.” ACS Photonics, 2025, 12(6), 3198–3207.

Research Impact

The research contributions of Tiange Zhao have influenced ongoing developments in scalable two-dimensional material synthesis and infrared optoelectronic technologies. His work on substrate engineering and material transfer methodologies supports improved industrial applicability for two-dimensional semiconductor systems. Publications in high-impact journals, including an ESI Highly Cited Paper in Chemical Society Reviews, reflect recognition within the international scientific community.[2]

In addition to scholarly publications, Zhao has received support through competitive research funding programs, including the China Postdoctoral Science Foundation, the National Postdoctoral Researchers Program, and the Chinese Academy of Sciences Special Research Assistant grant. He also participated in key provincial and municipal joint research projects in Guangdong Province related to basic and applied research.[3]

Award Suitability

Tiange Zhao demonstrates qualifications suitable for recognition in emerging research and advanced materials science award categories. His interdisciplinary research profile combines materials engineering, nanotechnology, and optoelectronics with practical applications in infrared sensing technologies. The combination of high-impact publications, funded research initiatives, and contributions to scalable material synthesis techniques indicates substantial academic and technological relevance within the field of modern optoelectronics.[4]

Conclusion

Tiange Zhao’s research activities contribute to the advancement of two-dimensional material synthesis and infrared optoelectronic device engineering. Through his investigations into wafer-scale growth, topological insulator systems, and broadband photodetection technologies, he has participated in the development of scalable solutions relevant to future photonic and sensing applications. His scholarly output and research funding achievements position him as an emerging contributor within the fields of materials science and optoelectronics.

References

  1. Elsevier. (n.d.). Scopus author details: Tiange Zhao, Author ID 57825529200.
    https://www.scopus.com/authid/detail.uri?authorId=57825529200
  2. Zhao, T., et al. (2023). Substrate Engineering for Wafer-scale Two-dimensional Material Growth: Strategies, Mechanisms, and Perspectives. Chemical Society Reviews.
    DOI: https://doi.org/10.1039/D2CS00793A
  3. Zhao, T., et al. (2024). Wafer-scale transfer of two-dimensional materials with UV tape. Nature Electronics.
    DOI: https://doi.org/10.1038/s41928-023-01076-6
  4. Zhao, T., et al. (2024). Topological insulator Bi2Se3 heterojunction with a low dark current for mid-wave infrared photodetection. ACS Photonics.
    DOI: https://doi.org/10.1021/acsphotonics.4c00219
  5. Duan, S., Zhao, T.*, et al. (2025). Controlled Synthesis of Bi2O2Te Nanosheets for High-Performance Broadband Photodetectors. ACS Photonics.

Panagiotis Bousoulas | Materials Science | Research Excellence Award

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Assist. Prof. Dr. Panagiotis Bousoulas | Materials Science | Research Excellence Award

National Technical University of Athens | Greece

Assist. Prof. Dr. Panagiotis Bousoulas is an emerging scientific leader in the field of developmental biology and epigenetics, with a research program focused on understanding novel DNA and RNA modifications and their role in neural function, development, and disease. His academic foundation spans prestigious institutions, beginning with a BSc in Medical Genetics from the University of Leicester, followed by doctoral training at the University of Cambridge, UK, where he completed PhD rotations under globally recognized pioneers, including Sir John B. Gurdon, Sarah Bray, and Azim Surani. Prior to this, he studied Physics at the University of Stuttgart, Germany—a multidisciplinary background that contributes to his systems-level scientific approach. Dr. Bousoulas’ professional trajectory includes advanced postdoctoral research at major international institutions such as the Gurdon Institute (Cambridge), Yale University, and the Broad Institute/Harvard University, where he worked with Sir John B. Gurdon, Antonio Giraldez, and John Rinn—leading authorities in developmental biology and genomics. He currently serves as a Principal Investigator at the Chinese Institute for Brain Research (CIBR), where he leads an independent research group supported by multiple competitive funding awards, including the Beijing Natural Science Foundation, Human Frontiers Long-Term Fellowship, Isaac Newton Trust, and a major BBSRC project grant exceeding £830,000. His groundbreaking work contributed to the discovery of methylated deoxyadenosine (m6dA) in vertebrate genomes, reported in Koziol et al., 2015, which opened an entirely novel field in vertebrate epigenetics. His research continues to advance global understanding of how DNA and RNA chemical modifications regulate brain development and contribute to neurological disease, with potential applications in diagnostics and therapeutics. Recognized for excellence early in his career, Dr. Bousoulas has received awards from the AAAS Science Journal, Queen Elizabeth II, the Wellcome Trust, and Cambridge European Trust. His research has significant societal impact, contributing to improved understanding of molecular mechanisms underlying brain disorders and offering potential routes toward medical innovation.

Profile: Scopus | ORCID

Featured Publications

  • (2025). Closed-loop CBRAM crossbar system toward hardware acceleration of quantum algorithms. IEEE Transactions on Circuits and Systems

  • (2025). Low-power perovskite-based memristors enable fused reservoir computing and neuromorphic vision with highly accurate color perception.

  • (2025). A physics-based compact SPICE model emulating volatile and non-volatile switching patterns to heart arrhythmia detection.

  • (2025). Highly reliable perovskite-based memristors using Ag nanoparticles/FA₂PbI₄ junctions for enhanced memory and optoelectronic synaptic performance.

  • (2025). Low-power FA₂PbI₄/SiO₂ bilayer memristors with Pt nanoparticles exhibiting reconfigurable synaptic and neuron properties for compact optoelectronic neuromorphic systems.

Francisco Javier GOMEZ CANO | Materials Science | Editorial Board Member

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Mr. Francisco Javier GOMEZ CANO | Materials Science | Editorial Board Member

Le Mans Université-CINVESTAV | France

Francisco Javier-Gómez Cano is a multidisciplinary researcher currently pursuing a dual PhD in Physics at Le Mans Université, France (2021–present) and in Nanoscience and Nanotechnology at CINVESTAV-IPN, Mexico (2020–present). His research focuses on the design, synthesis, and characterization of TiO₂–graphene oxide (GO) nanocomposites, with particular emphasis on photocatalysis, water remediation, adsorption mechanisms, and ceramic-based functional materials. With a strong background spanning ceramic engineering and environmental engineering, he integrates experimental materials science with computational approaches, including density functional theory (DFT) to elucidate bandgap modulation, interfacial interactions, and photocatalytic pathways in advanced composites. Francisco has authored and co-authored more than 10 peer-reviewed research papers, including contributions to Journal of Nanomaterials, Ceramics International, Journal of Environmental Chemical Engineering, Crystals, and IEEE conference proceedings. His work collectively addresses photocatalytic degradation of environmental pollutants, sol-gel and dip-coating thin films, graphene oxide chemistry, perovskite film optimization, and metal oxide nanostructures. His publications have gained growing visibility within the materials science and nanotechnology communities, supported by international collaborations with researchers in France, Mexico, Argentina, India, and Poland. He has presented his research in multiple international forums, including the International Materials Research Congress (IMRC), the International Conference on Electrical Engineering, Computing Science, and Automatic Control (CCE), and the SAM Congress. He has served as session chair, co-organizer, and invited speaker across several events, reflecting his leadership in academic dissemination. His membership roles include the Royal Society of Chemistry (RSC) and the Mexican Materials Society, and he previously served as President of the CINVESTAV Student Council.

Profiles: Scopus | ORCID

Featured Publications

Cano, F. J., Sánchez-Albores, R., Ashok, A., Escorcia-García, J., Cruz-Salomón, A., Reyes-Vallejo, O., Sebastian, P. J., & Velumani, S. (2025). Carica papaya seed-derived functionalized biochar: An environmentally friendly and efficient alternative for dye adsorption. Journal of Materials Science: Materials in Electronics.

Aguila-Rosas, J., Cano, F. J., Nagaya, A., Quirino-Barreda, C. T., Martínez Ortiz, M. de J., Guzmán Vargas, A., Ibarra, I. A., & Lima, E. (2025). MOF-composites for adsorption and degradation of contaminants in wastewater. Chemical Communications.

Ashok, A., Acosta, D., Camarillo, E., Cano, F. J., Reyes-Vallejo, O., & Olvera, M. D. L. L. (2025). Sustainable design on manufacturing V₂O₅ nanoparticles and analysis of their material properties for CO gas sensors. Advances in Natural Sciences: Nanoscience and Nanotechnology.

Adhikari, A., Acosta Najarro, D. R., Reyes-Gasga, J., Camarillo Garcia, E., Merino Alama, T. K., Reyes-Vallejo, O., Cano, F. J., & Olvera Amador, M. de la L. (2025). Preparation and characterization of vanadium–titanium oxide thin films via the evaporation technique followed by the post-annealing treatment. Materials Chemistry and Physics.

Reyes-Vallejo, O., Cano, F. J., Sánchez-Albores, R., Luévano-Hipólito, E., Serrano-Ramirez, R. P., Hernández-Cruz, M. C., Valencia, D., Torres-Martínez, L. M., & Velumani, S. (2025). Sustainable combustion synthesis of BiVO₄ using orange peel for photocatalytic applications. Journal of Materials Science: Materials in Electronics.

Mohammed Laid Tedjani | Materials Science | Editorial Board Member

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Dr. Mohammed Laid Tedjani | Materials Science | Editorial Board Member

El oued university | Algeria

Dr. Mohammed Laid Tedjani is a Process Engineering specialist at the Faculty of Technology, University of El-Oued, Algeria, where he also serves as a Temporary Professor. He earned his Ph.D. in Process Engineering in March 2022, following a Master’s degree in Petroleum Refining Engineering (2018) and a Bachelor’s degree in Refining and Petrochemicals (2016), consistently ranking first in his cohort with an outstanding academic record. His research spans process optimization, nanotechnology, material science, biosynthesis, antioxidant and antibacterial activity, chemical engineering, crystal engineering, numerical optimization, and petroleum engineering. Dr. Tedjani has established a strong scholarly presence, contributing to numerous peer-reviewed publications in high-impact journals such as the Journal of Molecular Structure, Journal of Cluster Science, Membranes, Textile Research Journal, Journal of Inorganic and Organometallic Polymers, and Ferroelectrics. His work has received growing visibility, reflecting impactful contributions in green synthesis of metal and metal-oxide nanoparticles, their physicochemical characterization, and applications in optoelectronics, catalysis, and bioactivity enhancement. He has also presented at international conferences, including the International Seminar on Green Chemistry and Sustainable Engineering. As a Publons Academy Certified Peer Reviewer, Dr. Tedjani has completed more than 20 reviews for reputable journals, demonstrating his active role in scientific quality assurance. His collaborative research network includes national and international scholars working across materials chemistry, nanoscience, electrochemistry, and environmental engineering. His publications continue to gain citations, highlighting the societal relevance of his work in sustainable materials, green nanotechnology, and environmental remediation.

Profiles: Scopus | ORCID | Google Scholar

Featured Publications

1. Laouini, S. E., Bouafia, A., Soldatov, A. V., Algarni, H., Tedjani, M. L., Ali, G. A. M., … (2021). Green synthesized Ag/Ag₂O nanoparticles using aqueous leaves extracts of Phoenix dactylifera L. and their azo dye photodegradation. Membranes, 11(7), 468.

2. Gherbi, B., Laouini, S. E., Meneceur, S., Bouafia, A., Hemmami, H., Tedjani, M. L., … (2022). Effect of pH value on the bandgap energy and particles size for biosynthesis of ZnO nanoparticles: Efficiency for photocatalytic adsorption of methyl orange. Sustainability, 14(18), 11300.

3. Bouafia, A., Laouini, S. E., Khelef, A., Tedjani, M. L., & Guemari, F. (2021).
Effect of ferric chloride concentration on the type of magnetite (Fe₃O₄) nanoparticles biosynthesized by aqueous leaves extract of Artemisia and assessment of their antioxidant properties. Journal of Cluster Science, 32(4), 1033–1041.

4. Laid, T. M., Abdelhamid, K., Eddine, L. S., & Abderrhmane, B. (2021).
Optimizing the biosynthesis parameters of iron oxide nanoparticles using central composite design. Journal of Molecular Structure, 1229, 129497.

5. Bouafia, A., Laouini, S. E., Tedjani, M. L., Ali, G. A. M., & Barhoum, A. (2022).
Green biosynthesis and physicochemical characterization of Fe₃O₄ nanoparticles using Punica granatum L. fruit peel extract for optoelectronic applications. Textile Research Journal, 92(15–16), 2685–2696.

Jing Ruan | Materials Science | Editorial Board Member

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Assoc Prof Dr. Jing Ruan | Materials Science | Editorial Board Member

Shanghai Jiao Tong University School of Medicine | China

Dr. Jing Ruan is an Associate Professor in the Department of Ophthalmology at the Shanghai Jiao Tong University School of Medicine and the Affiliated Ninth People’s Hospital. She earned her Ph.D. in Biomedical Engineering from Shanghai Jiao Tong University and completed earlier degrees in Materials Science & Engineering (B.S.) and Applied Chemistry (M.S.). Her research trajectory spans materials science, biomedical engineering, ophthalmology, and translational nanomedicine. Prior to her academic appointment, she contributed to drug discovery research at Lilly China Research and Development Center, strengthening her foundation in therapeutic innovations. Dr. Ruan’s research focuses on the design of implantable biomaterials and the molecular mechanisms underlying cellular responses. She is internationally recognized for her work in ocular oncology, particularly the epigenetic and pathogenic processes driving melanoma progression. Her interdisciplinary expertise extends to nanotechnology-based targeted cancer therapies, including gene nanocarriers, multimodal theranostic nanoprobes, and nano–immune adjuvants. Over the past five years, she has authored numerous high-impact publications in Acta Biomaterialia, Nano Today, Oncogene, Clinical and Translational Medicine, Bioactive Materials, and Advanced Science, reflecting significant contributions to cancer therapeutics, biomimetic scaffolds, nanotoxicology, and photodynamic therapy. Her collective body of work exceeds dozens of peer-reviewed papers, many of which involve collaborations with leading scientists such as Kam W. Leong, X.J. Loh, and X. Fan, underscoring her strong interdisciplinary and international research partnerships. Her research excellence has been recognized through multiple prestigious awards, including the Pujiang Award (2021), Rising Star Award (2017), and Outstanding Doctoral Dissertation Award (2016). Earlier distinctions such as the Young Artist Award and the First Ruth Mulan Chu Chao Scholarship highlight her longstanding academic merit.

Profiles: Scopus

Featured Publications

1. Ma, Y., Lin, H., Wang, P., Yang, H., Yu, J., Tian, H., Li, T., Ge, S., Wang, Y., Jia, R., Leong, K. W., & Ruan, J. (2022). A miRNA-based gene therapy nanodrug synergistically enhances pro-inflammatory antitumor immunity against melanoma. Acta Biomaterialia.

2. Ruan, J., Li, F., Tian, H., Yu, J., Deng, H., Ge, S., & Leong, K. W. (2022). A cascade FRET photosensitizer that enhances photodynamic therapy for ocular melanoma. Nano Today, 47, 101684.

3. Zhuang, A., Chai, P., Wang, S., Zuo, S., Yu, J., Jia, S., Ge, S., Jia, R., Zhou, Y., Shi, W., Xu, X., Ruan, J., & Fan, X. (2022). Metformin promotes histone deacetylation of optineurin and suppresses tumour growth through autophagy inhibition in ocular melanoma. Clinical and Translational Medicine, 12(1), e660.

4. Gu, X., Zhuang, A., Yu, J., Chai, P., Jia, R., & Ruan, J. (2022). Phase separation drives tumor pathogenesis and evolution: All roads lead to Rome. Oncogene, 41(11), 1527–1535.

5. Tian, H., Shi, H., Yu, J., Ge, S., & Ruan, J. (2022). Biophysics role and biomimetic culture systems of ECM stiffness in cancer EMT. Global Challenges, 6(6), 2100094.

Jacob Olchowka | Materials Science | Innovative Research Award

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Dr. Jacob Olchowka | Materials Science | Innovative Research Award

ICMCB (Institute of Condensed Matter Chemistry of Bordeaux), France

Dr. Jacob Olchowka is a French CNRS researcher in the field of material science with a specialization in electrochemical energy storage, particularly Na-ion/Li-ion batteries, hybrid supercapacitors, and direct recycling of lithium-ion batteries. He earned his Ph.D. in Material Science with very honorable mention through a joint program between the University of Lille, France, and the University of Siegen, Germany, following a Master’s degree in Chemistry, Energy, and Environment and a Bachelor’s degree in Physical Chemistry from the University of Lille, and more recently completed his Habilitation (HDR) at the University of Bordeaux in 2025. His professional career includes international postdoctoral experiences at the University of Geneva, Switzerland, and the University of Siegen, Germany, before securing a permanent CNRS position at ICMCB in 2017. His research interests cover synthesis and nanostructuration of electrode materials, surface modifications, operando and in-situ characterizations, crystallochemistry, and the regeneration of end-of-life electrodes. Skilled in advanced synthesis methods (solid-state, sol-gel, ionothermal, molten salt), particle morphology control, structural characterizations (XRD, Raman, IR, UV-vis, SEM, XAS), and electrochemical testing, he combines fundamental and applied expertise to address energy challenges. His contributions include 56 peer-reviewed publications, 4 patents, more than 900 citations, an h-index of 18, and leadership in major projects such as ANR NANO-INSPIRE, REGENERATE, and H-BAT, alongside supervision of Ph.D. and postdoctoral researchers, teaching commitments at the University of Bordeaux, and involvement in European programs such as Battery 2030+ and H2020 NAIMA. He has received notable honors, including the ANR Young Researcher Grant, Fondation Roi Baudouin – Solvay Grant, and recognition for his research presentations, while being an active member of RS2E, Alistore, and the French Chemical Society. With his strong international collaborations, scientific leadership, and commitment to mentoring, Dr. Olchowka has established himself as an influential researcher whose work significantly advances sustainable energy storage and positions him as a future leader in the global transition toward greener technologies.

Profile: Scopus | ORCID | LinkedIn

Featured Publications

Croguennec, L., Duttine, M., Grebenshchikova, A., Lyonnard, S., Olchowka, J., Simonin, L., & Stievano, L. (2027). Multi-scale multi-techniques investigations of Li-ion batteries: Towards a European Battery Hub [Dataset]. European Synchrotron Radiation Facility.

Grebenshchikova, A., Olchowka, J., Simonin, L., Yaroslavtsev, S., Duttine, M., Fauth, F., Stievano, L., Masquelier, C., & Croguennec, L. (2025). Na₂Fe₃(SO₄)₄: A zero‐strain sustainable positive electrode material for Na‐ion batteries. Angewandte Chemie International Edition. Advance online publication.

Grebenshchikova, A., Olchowka, J., Simonin, L., Yaroslavtsev, S., Duttine, M., Fauth, F., Stievano, L., Masquelier, C., & Croguennec, L. (2025). Na₂Fe₃(SO₄)₄: A zero‐strain sustainable positive electrode material for Na‐ion batteries. Angewandte Chemie. Advance online publication.

Grebenshchikova, A., Olchowka, J., Simonin, L., Duttine, M., Weill, F., Suard, E., Masquelier, C., & Croguennec, L. (2025). NaSICON NaFe₂PO₄(SO₄)₂ revisited: Insights into the crystal structure and electrochemical performance. ACS Applied Energy Materials. Advance online publication.

Hayagan, N., Guillou, P., Olchowka, J., Ercicek, F., Lecoutre, C., Nguyen, O., Aymonier, C., Marre, S., Erriguible, A., & Philippot, G. (2025). Understanding the role of pressurized CO₂ in the direct recycling process of Li-ion battery positive electrode. Journal of CO₂ Utilization, 103, 103080.

Mehdi Rafizadeh | Materials Science | Best Research Article Award

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Prof. Dr. Mehdi Rafizadeh | Materials Science | Best Research Article Award

Amirkabir University of Technology, Iran

Prof. Dr. Mehdi Rafizadeh, is a distinguished Professor in the Department of Polymer Engineering and Color Technology at Amirkabir University of Technology, Iran, where he has established himself as a leading authority in polymer science and chemical engineering. He earned his B.Sc. (1989) and M.Sc. (1991) in Chemical Engineering from Amirkabir University of Technology, followed by a Ph.D. in Chemical Engineering (Polymer) from McGill University, Montreal, Canada, in 1997. With over three decades of academic and research excellence, his professional experience spans teaching, supervising graduate students, conducting applied research, and leading industrial projects that bridge the gap between academia and industry. His research interests focus on polymer engineering, materials science, color technology, sustainable chemical processes, and industrial applications of advanced polymeric materials. He has an impressive scholarly record, with 83 peer-reviewed journal publications, 163 conference papers, two books, and 12 industrial research projects, along with a Scopus profile showing 92 indexed documents, 1,161 citations, and an h-index of 14, which testify to his global academic impact. His research skills encompass polymer synthesis and characterization, advanced chemical engineering methodologies, industrial process optimization, and interdisciplinary collaboration, making him a highly versatile researcher and mentor. Throughout his career, Prof. Rafizadeh has been recognized with several honors for his contributions to polymer research and his dedication to academic excellence, including leadership roles in academic platforms and involvement in international scientific communities. His achievements reflect a commitment not only to advancing scientific knowledge but also to mentoring young researchers, promoting industrial innovation, and contributing to the broader scientific community. In conclusion, Prof. Dr. Mehdi Rafizadeh’s exceptional academic background, impactful research contributions, strong international collaborations, and dedication to education and industrial development make him a highly respected scholar and deserving candidate for recognition in the global scientific community.

Profile: Scopus | ORCID | Google Scholar

Featured Publications

Neghlani, P. K., Rafizadeh, M., & Taromi, F. A. (2011). Preparation of aminated-polyacrylonitrile nanofiber membranes for the adsorption of metal ions: Comparison with microfibers. Journal of Hazardous Materials, 186(1), 182–189.

Fallahi, D., Rafizadeh, M., Mohammadi, N., & Vahidi, B. (2008). Effect of applied voltage on jet electric current and flow rate in electrospinning of polyacrylonitrile solutions. Polymer International, 57(12), 1363–1368.

Rafizadeh, M., Patterson, W. I., & Kamal, M. R. (1996). Physically-based model of thermoplastics injection molding for control applications. International Polymer Processing, 11(4), 352–362.

Zahedi, A. R., Rafizadeh, M., & Ghafarian, S. R. (2009). Unsaturated polyester resin via chemical recycling of off‐grade poly(ethylene terephthalate). Polymer International, 58(9), 1084–1091.

Ahmadi, R., Alivand, M. S., Tehrani, N. H. M. H., Ardjmand, M., Rashidi, A., & Rafizadeh, M. (2021). Preparation of fiber-like nanoporous carbon from jute thread waste for superior CO₂ and H₂S removal from natural gas: Experimental and DFT study. Chemical Engineering Journal, 415, 129076.

Rafael Bernardo Carmona-Paredes | Materials Science | Best Researcher Award

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Dr. Rafael Bernardo Carmona-Paredes | Materials Science | Best Researcher Award

National Autonomous University of Mexico | Mexico

Dr. Rafael Bernardo Carmona-Paredes is a highly respected academic and researcher specializing in hydraulic engineering, water resources management, and dynamic systems. With a career spanning over four decades, he has contributed extensively to both theoretical and applied aspects of water systems engineering. Currently serving at the Universidad Nacional Autónoma de México (UNAM), Dr. Carmona has dedicated his career to advancing hydraulic transients, pumping systems, aquifer recharge, and optimization of water distribution systems. His strong academic background, combined with innovative research and teaching, has enabled him to influence both national and international projects in water management and infrastructure. He has published widely in prestigious journals indexed in Scopus and JCR, authored book chapters, and developed patents related to hydraulic simulation and optimization. Dr. Carmona is also recognized for mentoring young researchers, guiding graduate students, and collaborating with institutions across Latin America and Europe. His professional excellence is further evident in his leadership roles within engineering associations and his frequent participation in international congresses. With a unique balance of academic rigor, applied engineering expertise, and societal impact, Dr. Carmona continues to be a leading figure in advancing sustainable solutions for global water challenges.

Professional Profile

Scopus Profile

Education

Dr. Rafael Bernardo Carmona-Paredes pursued his academic training entirely at the prestigious Universidad Nacional Autónoma de México (UNAM), where he cultivated a multidisciplinary foundation bridging physics, control engineering, and mechanical engineering. He completed his Bachelor’s degree in Physics, which provided him with a solid understanding of fundamental scientific principles, including fluid dynamics, mechanics, and applied mathematics. Motivated by the challenges of engineering applications, he advanced to earn his Master’s degree in Control Engineering, where he specialized in system modeling, dynamic controls, and mathematical optimization. This phase of study laid the groundwork for his future work in hydraulic systems and dynamic behavior of pipelines and water distribution networks. Building upon his expertise, Dr. Carmona earned his Ph.D. in Mechanical Engineering at UNAM, with a dissertation that focused on mathematical modeling for navigation and port water areas. His doctoral research represented an early integration of computational methods with hydraulic and mechanical engineering, pioneering approaches that remain highly relevant today. This combination of degrees reflects his progression from theoretical sciences to applied engineering, equipping him with the interdisciplinary knowledge essential for addressing complex problems in hydraulic engineering and water resources management.

Professional Experience

Dr. Rafael Bernardo Carmona-Paredes has held an illustrious professional career rooted in both academia and applied research. He has been a professor and researcher at the Faculty of Engineering, Universidad Nacional Autónoma de México (UNAM), where he has significantly contributed to teaching, supervising graduate students, and leading research initiatives. Over the years, he has spearheaded numerous national and international projects related to hydraulic engineering, water distribution systems, and aquifer management. His professional expertise extends beyond teaching into consultancy and applied engineering, where he has collaborated with governmental agencies, private organizations, and research institutions in solving water management challenges. Dr. Carmona has also been actively involved in presenting his work at major international forums such as the International Association for Hydro-Environment Engineering and Research (IAHR) and Latin American Hydraulic Congresses, establishing himself as a global voice in water engineering. He has contributed to the development of simulation models for transient flows, optimization techniques for pumping systems, and innovative strategies for aquifer recharge. His professional experience showcases a seamless blend of academic leadership, practical problem-solving, and active participation in the global engineering community, making him a sought-after expert in his field.

Research Interests

Dr. Rafael Bernardo Carmona-Paredes’ research interests focus on advancing the science and practice of hydraulic engineering, with a special emphasis on addressing water resource challenges. His primary area of interest lies in hydraulic transients, where he explores the dynamic behavior of water flow in pressurized systems and pipelines, including the effects of viscoelastic properties. He is deeply engaged in the study of pumping systems, their energy efficiency, and methods for optimizing their operation to achieve sustainable outcomes. Another significant focus of his research is aquifer recharge and groundwater management, where he integrates hydrological modeling with engineering approaches to enhance water security. Dr. Carmona also investigates reservoir operation policies, developing computational models that help optimize water storage and distribution under varying climatic and demand conditions. His work extends into mathematical modeling and control systems, leveraging his interdisciplinary background in physics and engineering to simulate complex water systems. By combining theoretical models with practical applications, his research provides innovative solutions for urban water distribution, infrastructure resilience, and sustainable resource management. His interests align with global efforts to ensure water sustainability, positioning his contributions as both regionally impactful and internationally relevant.

Research Skills

Dr. Rafael Bernardo Carmona-Paredes possesses a rich skill set that spans theoretical, computational, and applied aspects of hydraulic engineering and water resource systems. His expertise in mathematical modeling and simulation allows him to design complex models of hydraulic transients, aquifer recharge, and pumping systems with high accuracy. He is skilled in control systems engineering, applying advanced optimization methods to improve the performance and efficiency of water distribution networks. His proficiency extends to computational fluid dynamics (CFD), enabling him to analyze fluid behavior under transient and steady-state conditions. Additionally, Dr. Carmona demonstrates strong abilities in reservoir operation modeling, particularly in developing strategies for water conservation and sustainable supply. His technical strengths are complemented by his knowledge of hydrological data analysis, dynamic system modeling, and viscoelastic pipeline behavior. Beyond technical skills, he excels in research communication through scholarly publications, book chapters, and patents, as well as in collaborative skills through partnerships with international universities and engineering institutions. His ability to integrate theoretical rigor with practical applications reflects his comprehensive research capabilities, equipping him to address multidisciplinary challenges in water engineering and contribute to sustainable development goals.

Awards and Honors

Over the course of his career, Dr. Rafael Bernardo Carmona-Paredes has been recognized with numerous academic and professional honors for his contributions to hydraulic engineering and water resource management. His pioneering research has led to over 200 scientific publications in high-impact journals and conferences, many of which are indexed in Scopus and JCR, highlighting his influence in the global academic community. He has also authored book chapters and holds patents in hydraulic simulation systems, showcasing his ability to translate research into practical innovations. Dr. Carmona has been invited to present at international forums, including IAHR and Latin American Hydraulic Congresses, where his work has been acknowledged by peers worldwide. His role as a mentor and educator at UNAM has also earned him recognition within academic circles for shaping future generations of engineers and researchers. In addition to academic achievements, Dr. Carmona’s applied engineering solutions for aquifer management and hydraulic transients have earned him commendations from research and professional organizations. Collectively, these awards and honors reflect not only his scholarly excellence but also his significant impact on sustainable water engineering practices, both regionally and internationally.

Publication Top Notes

  1. Unsteady and Steady Flow Control on Pumping Systems — 1990

  2. Damp trend Grey Model forecasting method for airline industry — 2013

  3. Pressure management in water distribution systems using a self-tuning controller to distribute the available potable water with equality — 2018

  4. Protecting a Pumping Pipeline System from Low Pressure Transients by Using Air Pockets: A Case Study — 2019

  5. A Unified Hydrogeological Conceptual Model of the Mexico Basin Aquifer after a Century of Groundwater Exploitation — 2022

  6. Challenges and Experiences of Managed Aquifer Recharge in the Mexico City Metropolitan Area — 2022

  7. Use of evolutionary computation and guide curves to optimize the operating policies of a reservoir system established to supply drinking water — 2023

  8. Modeling Viscoelastic Behavior of HDPE Pipes Subjected to a Diametral Load Using the Standard Linear Solid Model — 2025

Conclusion

Dr. Rafael Bernardo Carmona-Paredes stands out as a visionary researcher and academic leader in the field of hydraulic engineering and water resource management. His academic journey from physics to mechanical engineering, paired with his practical expertise, has positioned him as a pioneer in developing innovative solutions for water-related challenges. His contributions extend from theoretical models of hydraulic transients to practical strategies for aquifer recharge and water distribution optimization, bridging the gap between science and application. Beyond his research, Dr. Carmona’s dedication to teaching and mentoring reflects his commitment to shaping future engineers, while his collaborations with global institutions highlight his influence beyond national borders. His vast publication record, patents, and recognition at international forums serve as a testament to his academic excellence and societal impact. Moving forward, his continued focus on sustainability, technological innovation, and global collaboration promises to further strengthen his contributions to water security and hydraulic engineering. For his pioneering achievements, leadership, and dedication, Dr. Rafael Bernardo Carmona-Paredes is rightfully considered a leading figure in his field and a deserving candidate for distinguished academic recognition.

Qabas Khalid Naji | Material Science | Best Researcher Award

Published on by World Science Awards

Assist. Prof. Dr. Qabas Khalid Naji | Material Science | Best Researcher Award

University of Babylon | Iraq

Assist. Prof. Dr. Qabas Khalid Naji is a distinguished academic and researcher in the field of Materials and Metallurgical Engineering, with a specialized focus on biomaterials, coatings, and advanced surface modification technologies. With her Ph.D. in Metallurgical Engineering from the University of Babylon, she has established herself as an expert in developing innovative solutions for biomedical applications and industrial engineering challenges. Her doctoral work emphasized Micro-Arc Oxidation (MAO) processes, improving corrosion resistance, mechanical properties, and structural performance of titanium-based alloys, which are highly relevant in medical implant technologies. Dr. Qabas has authored and co-authored multiple research papers in high-impact journals, such as Materials Today: Proceedings, Key Engineering Materials, and Journal of Physics: Conference Series. She has also contributed as a reviewer and evaluator for numerous international conferences, highlighting her academic recognition. Beyond research, she has played an important role in teaching and mentoring students, serving as a lecturer at both the University of Babylon and Al-Mustaqbal University College. Her academic journey reflects a balance of research excellence, teaching leadership, and professional service, positioning her as one of the promising scholars in her field with significant contributions to both science and education.

Professional Profile

Scopus | Google Scholar

Education

Assist. Prof. Dr. Qabas Khalid Naji has pursued a strong academic pathway rooted in Materials and Metallurgical Engineering. She began her higher education at the University of Babylon, where she obtained her Bachelor of Science (B.Sc.) in Material Engineering / Metallurgical Engineering. During this phase, she developed a foundational understanding of material structures, mechanical properties, and engineering applications. She further advanced her expertise by completing a Master of Science (M.Sc.) in Metallurgical Engineering, focusing on metal processing, surface engineering, and quality enhancement techniques. This period allowed her to engage in advanced laboratory practices and develop independent research skills. Her academic journey culminated with a Doctor of Philosophy (Ph.D.) in Metallurgical Engineering, where her dissertation was centered on bioceramic coatings and the application of Micro-Arc Oxidation techniques to improve the biomedical performance of alloys. The Ph.D. phase represented a crucial step in her academic development, equipping her with both theoretical knowledge and practical expertise to carry out innovative, application-oriented research. Her educational background demonstrates a consistent dedication to advancing materials science, and it has laid the foundation for her career as a researcher, lecturer, and scientific contributor in both academic and professional domains.

Professional Experience

Assist. Prof. Dr. Qabas Khalid Naji has built a diverse academic and teaching career with roles that combine research, teaching, and administrative responsibilities. She began her academic career as an external lecturer at the University of Babylon, teaching courses in Laboratory Metals Machining, Industrial Engineering, and Quality Control, where she applied her strong technical knowledge to guide students in practical and theoretical aspects of materials science. She later served as a lecturer at Al-Mustaqbal University College in the Department of Biomedical Engineering, where she also undertook additional responsibilities as a quality officer, ensuring academic and institutional standards. she was officially appointed as a faculty member at the University of Babylon, College of Materials Engineering, where she continues to serve as an Assistant Professor. Alongside teaching, she has played an important role in curriculum design, quality management, and student mentorship. Dr. Qabas has also acted as an evaluator for international research conferences, which highlights her recognition in the global academic community. Her professional journey reflects a strong commitment to education, scientific innovation, and academic leadership, ensuring her continuous growth as a researcher and educator in metallurgical and materials engineering.

Research Interests

Assist. Prof. Dr. Qabas Khalid Naji’s research interests lie primarily in biomaterials, coatings, and advanced metallurgical engineering applications. Her doctoral research focused on the surface modification of titanium alloys through Micro-Arc Oxidation (MAO), which significantly enhances mechanical strength, corrosion resistance, and biocompatibility, making it ideal for biomedical implants. She has also explored layered bioceramic coatings, including hydroxyapatite and titanium dioxide composites, which contribute to advancements in medical device technology. Beyond biomaterials, her research extends into nanostructured materials, corrosion science, heat treatment effects, and aluminum alloy processing, showcasing her ability to bridge both theoretical materials science and practical engineering applications. Her recent publications have investigated the impact of melting and casting parameters on aluminum alloys, reflecting her wide scope of expertise. Dr. Qabas is particularly interested in how surface engineering techniques can improve material performance in biomedical, aerospace, and industrial sectors. She continues to expand her research through collaborative projects, interdisciplinary studies, and applied experimental work, ensuring her contributions remain at the forefront of materials innovation, biomedical engineering, and sustainable industrial technologies. Her research agenda demonstrates a clear vision of bridging scientific discovery with real-world technological applications.

Research Skills

Over the course of her academic and professional journey, Assist. Prof. Dr. Qabas Khalid Naji has developed a comprehensive set of research skills that span experimental, analytical, and academic domains. Her expertise lies in surface modification techniques such as Micro-Arc Oxidation (MAO), which she has extensively applied to titanium-based alloys for biomedical applications. She is skilled in materials characterization methods, including structural, mechanical, and corrosion property testing of advanced alloys and bioceramic coatings. Additionally, she has experience in heat treatment processes, alloy casting, and nanomaterial preparation, making her well-versed in both experimental and industrial metallurgical practices. On the academic side, she is proficient in scientific writing, peer reviewing, and presenting research at international conferences. She has participated in and completed multiple professional training courses in teaching methodology, computer applications, and engineering innovations, further enhancing her technical and academic competencies. Furthermore, Dr. Qabas has served as an evaluator and reviewer for various scientific conferences and research platforms, reflecting her recognition as an expert in her field. Her ability to combine theoretical analysis with experimental practice highlights her strong profile as a well-rounded researcher, capable of contributing both academically and industrially to materials science and engineering.

Awards and Honors

Throughout her career, Assist. Prof. Dr. Qabas Khalid Naji has received recognition for her academic and research contributions in the field of Materials and Metallurgical Engineering. She has been actively involved in evaluating and reviewing international research and scientific conferences, which reflects her respected standing within the global research community. Her publications in reputed, peer-reviewed journals and conference proceedings indexed in Scopus and Web of Science further highlight her scholarly impact. Among her notable works are contributions to journals such as Materials Today: Proceedings, Key Engineering Materials, 3C Tecnología, and Journal of Physics: Conference Series, all of which underline her role as a productive and impactful researcher. She has also been invited to participate in scientific workshops, training courses, and professional development programs, earning certifications that enhance both her teaching and research expertise. While her career is still progressing, her consistent contributions in biomaterials, alloy modifications, and applied surface engineering techniques stand as significant honors to her academic profile. Her growing citation record and recognition as a reviewer reflect her standing as an emerging leader in her discipline, with strong potential to achieve further international awards and honors in the near future.

Publication Top Notes

  • Investigations of structure and properties of layered bioceramic HA/TiO₂ and ZrO₂/TiO₂ coatings on Ti-6Al-7Nb alloy by micro-arc oxidation — 2022 — 20 citations

  • The surface modification of pure titanium by micro-arc oxidation (MAO) process — 2021 — 10 citations

  • Effect of tool shape geometry and rotation speed in friction stir welding of 2024-T3 — 2016 — 5 citations

  • Plasma Electrolytic Oxidation of Nanocomposite Coatings on Ti-6Al-7Nb alloy for Biomedical Applications — 2024 — 2 citations

  • Study of the Effect of Melting and Casting Temperature and Heat Treatment on the Mechanical Properties of Aluminum 7075 — 2024

  • Micro-arc oxidation enhances mechanical properties and corrosion resistance of Ti-6Al-7Nb alloy — 2023

  • Deposition of Layered Bioceramic HA/TiO₂ Coatings on Ti-6Al-7Nb Alloys Using Micro-Arc Oxidation — 2022

Conclusion

Assist. Prof. Dr. Qabas Khalid Naji is an exemplary academic and researcher who has made meaningful contributions to metallurgical and materials engineering, particularly in the area of biomaterials and advanced coating technologies. Her educational journey from B.Sc. to Ph.D. at the University of Babylon reflects her dedication to academic excellence, while her professional experiences as a lecturer, quality officer, and assistant professor demonstrate her commitment to teaching, mentoring, and research leadership. With impactful publications in international journals and presentations in scientific conferences, she has established her research visibility at both national and international levels. Her skills in surface engineering, corrosion science, and biomedical applications highlight her capacity to address pressing challenges in both industrial and medical fields. Beyond research, her involvement in conference evaluation, training courses, and academic quality management underscores her service to the scientific community. Looking ahead, Dr. Qabas is well-positioned to expand her global collaborations, publish in higher-impact journals, and take on greater leadership roles in international research networks. Her achievements and potential make her highly deserving of recognition, such as the Best Researcher Award, reflecting her growing impact in advancing science, engineering, and education.