Kaniza Islam | Electrochemistry | Best Researcher Award

Published on by Analytical Chemistry

Ms. Kaniza Islam | Electrochemistry | Best Researcher Award

The Ohio State University | United States

Profiles

Scopus
Google scholar

Early Academic Pursuits

Kaniza Islam began her academic journey in the field of naval architecture and marine engineering, laying a strong foundation in structural analysis, mechanics, and computational modeling. Her undergraduate thesis addressed the structural behavior of ship girders under uniformly distributed loading, showcasing early proficiency in applied mechanics and problem-solving. Her exceptional academic record reflects a consistent commitment to academic excellence and technical depth.

Professional Endeavors

Building on her undergraduate background, Kaniza transitioned into the field of mechanical and aerospace engineering, where she gained comprehensive research and teaching experience across several academic institutions. Her professional journey includes roles as a lecturer, graduate teaching assistant, and research associate. These positions have allowed her to contribute meaningfully to both academic instruction and advanced engineering research, particularly in energy storage systems and combustion technologies.

Contributions and Research Focus

Kaniza’s primary research centers on the interfacial degradation mechanics of all-solid-state batteries (ASSBs), an area critical to advancing safe and efficient next-generation energy storage. Her work specifically investigates the role of elasto-plastic deformation in solid electrolytes and its effect on electrode–electrolyte interface stresses. This unique integration of fracture mechanics, continuum mechanics, and energy device modeling bridges theoretical understanding with real-world application. Her contributions aim to mitigate degradation mechanisms and improve the mechanical reliability of ASSBs.

Impact and Influence

Her research is already influencing the understanding of mechanical interactions in electrochemical systems. With a publication in a reputed energy storage journal and poster presentations at institutional research events, her work contributes to the foundational understanding needed for the development of durable and efficient solid-state batteries. Additionally, her role as a peer reviewer for the American Society of Mechanical Engineers (ASME) reflects her growing reputation within the academic community.

Technical Skills

Kaniza has developed an impressive technical toolkit through rigorous coursework and research. Her skills encompass continuum mechanics, strength of materials, elasticity, and fracture mechanics, along with modeling ceramic and polymer materials. She is also proficient in energy device design and simulation, virtual modeling of combustion systems, and the use of computational tools for mechanical and materials analysis. These competencies are critical to her work on solid-state battery degradation and broader engineering problems.

Teaching Experience

She has extensive teaching experience, both as a lecturer and a teaching associate. She has delivered over 350 hours of theoretical instruction and has administered multiple undergraduate engineering courses, including mechanical systems, thermal fluids, and measurement and data analysis. Her ability to explain complex topics to diverse audiences and mentor undergraduate research projects highlights her strong pedagogical capabilities and dedication to academic mentorship.

Legacy and Future Contributions

Kaniza Islam’s work sits at the intersection of mechanics and electrochemistry, addressing one of the key challenges in energy storage interfacial mechanical failure. Her current and future research is likely to contribute significantly to the development of longer-lasting, safer batteries for electric vehicles and grid storage. As she advances in her doctoral studies, her work is expected to yield deeper insights and practical solutions, positioning her as a rising expert in battery mechanics.

Notable Publication

  • The role of elasto-plastic deformation in solid electrolytes on the electrode–electrolyte interfacial stresses of all-solid-state batteries

  • Authors: Islam, K., & Katsube, N.

  • Journal: Journal of Energy Storage

  • Year: 2025

Conclusion

Kaniza Islam exemplifies the qualities of a forward-thinking researcher: technical depth, interdisciplinary expertise, and a commitment to solving real-world problems. Her combined contributions to teaching, research, and academic service make her a valuable asset to the engineering and energy storage community. With her growing influence and dedication, she is well poised to make lasting contributions in the field of solid-state batteries and mechanical engineering.

 

 

Neng Yu | Electrochemistry | Sustainable Chemistry Award

Published on by Analytical Chemistry

Assoc. Prof. Dr. Neng Yu | Electrochemistry | Sustainable Chemistry Award

East China University of Technology, China

Profiles

Early Academic Pursuits

Dr. Neng Yu began her academic journey with a strong foundation in Applied Chemistry, which cultivated her multidisciplinary perspective early on. She advanced through postgraduate studies in the same field before pursuing a doctoral degree in Optical Engineering. Her Ph.D. research was carried out at a leading national laboratory for optoelectronics in China, where she was mentored by distinguished faculty. These formative academic experiences shaped her expertise in electrochemistry, materials science, and nanotechnology—critical areas that would define her future research trajectory.

Professional Endeavors

Currently serving as an Associate Professor at East China University of Technology, Dr. Yu is also engaged internationally as a visiting scholar at a prominent Finnish institution. Her cross-border academic collaborations reflect a global outlook on applied physics and advanced materials. Within her home institution, she has spearheaded research in energy storage, battery materials, and flexible electronics, all while contributing actively to institutional research leadership and mentoring initiatives.

Research Focus and Contributions

Dr. Yu’s research centers on electrochemical energy storage systems, with a strong emphasis on aqueous zinc-ion batteries, lithium-ion batteries, and supercapacitors. She has made important contributions to the development of protective layers for zinc metal anodes that facilitate fast ion transfer and reduce dendrite formation. Additionally, she has developed binder-free electrode structures using CoSe₂ for lithium-ion batteries that offer improved electrical and ionic conductivity. Her work in designing flexible and high-performance supercapacitors—including waterproof, fiber-shaped, and stretchable devices—demonstrates her commitment to pioneering next-generation wearable energy technologies.

Funding and Research Leadership

Dr. Yu has consistently secured competitive funding as a principal investigator from national foundations, provincial science and technology departments, and open research platforms. Her research projects span areas such as new energy technologies, polymer nano-fabrication, and advanced energy materials. Her leadership in directing and completing these multidisciplinary projects showcases her ability to translate vision into impactful outcomes.

Impact and Influence

Dr. Yu’s contributions are widely recognized through over 30 scientific publications in high-impact journals such as Advanced Energy Materials and the Journal of Materials Chemistry. With 18 of these as first or corresponding author, she has demonstrated research leadership in both conception and execution. She also holds three authorized Chinese patents, signaling her focus on translating scientific research into practical and scalable innovations. Her work has significantly influenced progress in the fields of battery science and flexible energy systems.

Academic Citations and Recognition

Although specific citation metrics are not detailed, Dr. Yu’s consistent publication in leading international journals, combined with her funded research record, positions her as a respected figure within the scientific community. Her scholarly work continues to be referenced in research related to electrochemistry, nanomaterials, and advanced energy devices.

Technical Proficiency

Dr. Yu possesses a deep command of both synthesis and characterization techniques. She is proficient in material preparation methods such as hydrothermal synthesis, chemical vapor deposition, electrochemical deposition, anodic oxidation, and atomic layer deposition. Her analytical capabilities include techniques like XRD, SEM, TEM, XPS, AFM, and UV-Vis spectroscopy. She is also adept in the use of advanced electrochemical instrumentation including Autolab, PARSTAT 4000, CHI workstations, and LAND battery testing systems.

Scientific Communication and Computing

Dr. Yu is well-versed in scientific writing, peer review, and oral communication in English, which she employs effectively in both publishing and collaboration. Her computer literacy extends to software used for document preparation, data visualization, and image processing, such as Microsoft Office, 3D MAX, and Photoshop—tools that enhance the clarity and professional presentation of her research output.

Teaching and Mentorship

Beyond research, Dr. Yu has dedicated significant effort to teaching and mentoring. She has guided several student teams through innovation and entrepreneurship programs, both at national and provincial levels. Through these initiatives, she fosters research aptitude, creativity, and critical thinking in young scholars, reflecting her strong commitment to educational development and student success.

Legacy and Future Contributions

Dr. Yu continues to push boundaries in sustainable and flexible energy storage technologies. Her ongoing projects are aligned with global demands for environmentally friendly and portable energy solutions. As her career evolves, she is positioned to shape the future of energy materials through scientific innovation, interdisciplinary collaboration, and academic mentorship. Her legacy will be characterized by practical solutions grounded in strong scientific principles and a dedication to empowering the next generation of researchers.

Notable Publications

In situ electrochemical activation enabling high-performance cathodes for aqueous zinc-ion batteries
Authors: Qingpu Zeng, Shitong Zhou, Neng Yu*, Jiachen Huo, Changfang Sun, Kai Guo*
Journal: Journal of Materials Chemistry A
Year: 2025

Engineering aqueous electrolytes with a trifunctional additive for robust zinc anodes across a wide temperature range
Authors: Neng Yu, Shiya Lin, Shitong Zhou, Ye Li, Jiating Li, Qingpu Zeng, Lu Chen, Lei Wang, Kai Guo*, Xianfu Wang*, Yiju Li*
Journal: Energy Storage Materials
Year: 2025

Dual-function additive for simultaneously boosting the stability and energy density of aqueous zinc ion hybrid capacitors
Authors: Kai Guo, Jiating Li, Shiya Lin, Lu Chen, Neng Yu*, Yiju Li*
Journal: Chinese Chemical Letters
Year: 2025

Metallic Vanadium Activated by In-Situ Dissolution-Deposition Process for Superior Aqueous Zinc Ion Battery Cathode
Authors: Kai Guo, Ye Li, Changchen Yang, Yijing Xiang, Shanqi Pan, Qingpu Zeng, Zhuyao Li, Neng Yu*, Xianfu Wang*
Journal: Chemical Communications
Year: 2025

Highly Reversible Zinc Anode Enabled by Trifunctional Diethylenetriaminepentaacetic Acid Additive
Authors: Shiya Lin, Wang Zhao, Yisha Guo, Neng Yu*, Kai Guo*, Xianfu Wang*
Journal: ACS Energy Letters
Year: 2024

Keshavananda Prabhu C P | Electrochemistry and Synthesis | Best Researcher Award

Published on by Analytical Chemistry

Dr. Keshavananda Prabhu C P | Electrochemistry and Synthesis | Best Researcher Award

Gachon University South Korea

👨‍🎓Profiles

🧑‍🎓 Early Academic Pursuits

He embarked on his academic journey with a strong foundation in chemistry. After completing his Master’s degree (M.Sc.) in Chemistry from the University of Mysore with first-class honors, he pursued a B.Ed. in Physical Science from the same university, graduating with distinction. His passion for advanced research led him to obtain a Ph.D. in Chemistry from Vijayanagara Sri Krishnadevaraya University, Ballari. His doctoral thesis, “Synthesis of Substituted N4 Macrocycles for Biological and Electrochemical Applications,” laid the groundwork for his subsequent research contributions.

🧑‍🔬 Professional Endeavors

He is currently an Assistant Professor at Gachon University, South Korea, contributing to cutting-edge research in OLED materials. His prior roles include serving as a Research Professor at Kyung Hee University, Seoul, where he specialized in OLED and thermally activated delayed fluorescence (TADF) materials, and as a Guest Faculty Member at Vijayanagara Sri Krishnadevaraya University.

🧪 Research Focus and Contributions

His research centers on the synthesis of innovative materials such as: OLED materials, including TADF, multi-resonance TADF (MR-TADF), and hyper-fluorescence materials, Electron Transporting Layer (ETL) materials and host materials for advanced display technologies, N4 Macrocyclic materials like phthalocyanines for biological and electrochemical applications.

Electrochemical Applications

He has conducted pioneering work in: Designing and fabricating electrochemical sensors with high sensitivity, Investigating electrocatalytic processes like hydrogen evolution reactions (HER) and oxygen evolution reactions (OER) for energy storage and conversion devices.

📊 Theoretical Insights

He applies DFT and TDDFT methods to understand photophysical and optoelectronic properties, enabling the development of efficient materials for OLEDs and energy applications.

🏆 Awards and Recognition

Dr. Prabhu’s contributions have earned him accolades, including the Best Paper Award at the Korean Optical Society’s 2022 Summer Academic Presentation for his work on “Deep Blue Multi-Resonant TADF Emitters” achieving over 30% EQE.

🧰 Technical Skills

Dr. Prabhu is proficient in various advanced techniques, including: Spectroscopic Analysis: UV-Vis, fluorescence spectroscopy, quantum yield determination, and transient PL spectra, Electrochemical Techniques: Cyclic Voltammetry (CV), Electrochemical Impedance Spectroscopy (EIS), and chronoamperometry, Characterization Tools: NMR, XRD, MALDI-TOF Mass Spectrometry, and HPLC (RP).

📚 Teaching Experience

Dr. Prabhu has demonstrated exceptional teaching skills as a Guest Faculty Member in India and now as an Assistant Professor in South Korea. His expertise and dedication have inspired numerous students in advanced chemistry and material science.

🌍 Impact and Influence

Dr. Prabhu’s research has significantly impacted fields such as: Biological Applications: Developing N4 macrocyclic materials for photodynamic therapy (PDT), Sensor Technology: Enhancing sensitivity and reliability for real-time detection, Energy Devices: Advancing electrocatalysis for renewable energy solutions.

✨ Legacy and Future Contributions

Dr. Prabhu envisions a future of transformative research in OLED materials for next-generation displays and sustainable energy solutions. His ongoing projects, including collaborations with industry leaders like SAMSUNG Display, aim to revolutionize energy-efficient display technologies and contribute to global advancements in material science.

📖Notable Publications

  1. Acceptor-donor-acceptor based thermally activated delayed fluorescent materials: structure-property insights and electroluminescence performances
    • Authors: Keshavananda Prabhu, C.P., Naveen, K.R., Hur, J.
    • Journal: Materials Chemistry Frontiers
    • Year: 2023
  2. Modular design for constructing narrowband deep-blue multiresonant thermally activated delayed fluorescent emitters for efficient organic light emitting diodes
    • Authors: Naveen, K.R., Lee, H., Seung, L.H., Muruganantham, S., Kwon, J.H.
    • Journal: Chemical Engineering Journal
    • Year: 2023
  3. Novel polymeric zinc phthalocyanine for electro-oxidation and detection of ammonia
    • Authors: Keshavananda Prabhu, C.P., Aralekallu, S., Palanna, M., Renuka, B., Sannegowda, L.K.
    • Journal: Journal of Applied Electrochemistry
    • Year: 2022
  4. Nanomolar detection of 4-nitrophenol using Schiff-base phthalocyanine
    • Authors: Sajjan, V.A., Aralekallu, S., Nemakal, M., Keshavananda Prabhu, C.P., Koodlur Sannegowda, L.
    • Journal: Microchemical Journal
    • Year: 2021
  5. Non-precious cobalt phthalocyanine-embedded iron ore electrocatalysts for hydrogen evolution reactions
    • Authors: Prabhu, C.P.K., Aralekallu, S., Sajjan, V.A., Kumar, S., Sannegowda, L.K.
    • Journal: Sustainable Energy and Fuels
    • Year: 2021
  6. Nanomolar detection of mercury(II) using electropolymerized phthalocyanine film
    • Authors: Palanna, M., Aralekallu, S., Keshavananda Prabhu, C.P., Mounesh, Sannegowda, L.K.
    • Journal: Electrochimica Acta
    • Year: 2021
  7. Phthalocyanine sheet polymer-based amperometric sensor for the selective detection of 2,4-dichlorophenol
    • Authors: Mohammed, I., Nemakal, M., Aralekallu, S., Keshavananda Prabu, C.P., Sannegowda, L.K.
    • Journal: Journal of Electroanalytical Chemistry
    • Year: 2020