Tianwei He | Chemistry and Materials Science | Best Researcher Award

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Prof Dr. Tianwei He | Chemistry and Materials Science | Best Researcher Award 

Yunnan University | China

Dr. Tianwei He is an internationally recognized materials scientist and computational chemist whose research advances the rational discovery and design of next-generation electrocatalysts for sustainable energy and chemical transformations. He is currently an Associate Professor at the School of Materials and Energy, Yunnan University, China, where he leads cutting-edge research at the intersection of density functional theory (DFT), nanocatalysis, and machine learning. His academic training and professional trajectory span leading institutions in China, Australia, Germany, and Macau, reflecting a strong global research footprint. Dr. He obtained his PhD in Computational Materials Science from Queensland University of Technology (QUT), Australia, following earlier degrees in Materials Science and Engineering. He subsequently held postdoctoral and assistant researcher positions at the Fritz Haber Institute of the Max Planck Society (Germany), University of Macau, and Queensland University of Technology, working under renowned scholars including Prof. Karsten Reuter, Prof. Hui Pan, and Prof. Aijun Du. These experiences shaped his expertise in theoretical catalysis, surface science, and reaction mechanism modeling. His research focuses on the computational discovery of novel nanocatalysts for key electrochemical and photocatalytic reactions within the C, N, O, and H cycles, including HER, OER, ORR, nitrogen reduction, CO/CO₂ reduction, and selective hydrogenation. By constructing structure- and composition-sensitive models using DFT, NEB, and molecular dynamics, Dr. He provides atomic-level insights into active sites, scaling relationships, and reaction pathways. In recent years, he has integrated machine learning approaches to accelerate catalyst screening and performance prediction. Dr. He has authored and co-authored an extensive body of high-impact publications in premier journals such as Journal of the American Chemical Society, PNAS, Chem, Advanced Materials, Advanced Energy Materials, Chemical Society Reviews, ACS Catalysis, and Small. With an h-index of 38, over 4,900 citations, and multiple ESI Highly Cited and Hot Papers, his work is widely recognized for its originality and influence in the catalysis community. His studies on single-atom catalysts, heteronuclear dual-atom systems, high-entropy catalysts, and low-dimensional heterostructures have significantly advanced understanding of catalytic stability, selectivity, and efficiency. In addition to research, Dr. He actively contributes to the scientific community as an invited reviewer for leading journals and as a member of early-career editorial boards for Materials Today Energy, Battery Energy, and Journal of Electrochemistry. Through sustained excellence in research, mentorship, and international collaboration, Dr. Tianwei He continues to play a pivotal role in shaping the future of computational catalysis and sustainable energy materials.

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Featured Publications

Pibo Liu | Chemistry | Best Researcher Award | 13553

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Assoc Prof Dr. Pibo Liu | Chemistry | Best Researcher Award

Assoc Prof Dr. Pibo Liu, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, China

Assoc. Prof. Dr. Pibo Liu, from the Dalian Institute of Chemical Physics, Chinese Academy of Sciences, is a distinguished polymer chemist known for his pioneering work in precision polymerization. With a Ph.D. in Polymer Science and postdoctoral training at KAUST, he has advanced the field through the development of novel catalysts and functional materials. His research on rare-earth and Lewis acid catalysts has led to significant innovations in elastomer and fluorosilicone synthesis. With 38 SCI-indexed publications, 11 patents (4 granted), and active international collaborations, Dr. Liu’s contributions continue to shape the future of high-performance polymer materials.

Author Profile

Scopus

Education

Dr. Pibo Liu began his academic journey with a strong foundation in polymer science, earning his Ph.D. from Dalian University of Technology, one of China’s most reputable institutions for materials and chemical engineering. During his formative years, he demonstrated a keen interest in macromolecular chemistry and polymer architecture, distinguishing himself through a meticulous approach to scientific inquiry. His doctoral research laid the groundwork for a career dedicated to precision polymerization techniques, emphasizing innovation, scalability, and structural control.

Building upon this robust academic background, Dr. Liu pursued a postdoctoral fellowship at the King Abdullah University of Science and Technology (KAUST) in Saudi Arabia. Under the mentorship of renowned polymer scientist Professor Nikos Hadjichristidis, he honed his expertise in advanced polymer synthesis methodologies. This international exposure deepened his scientific perspective, provided access to world-class research facilities, and helped establish his identity in the global polymer research community.

Experience

Dr. Liu currently serves as an Associate Professor at the Dalian Institute of Chemical Physics (DICP), Chinese Academy of Sciences, where he leads several cutting-edge research projects. His professional trajectory reflects a harmonious blend of academic excellence and applied innovation. At DICP, Dr. Liu heads two major projects: one funded by the National Natural Science Foundation of China (Youth Program) and another under the Youth Innovation Program of the institute.

He has successfully completed three industry projects and is presently engaged in an ongoing corporate partnership, demonstrating his ability to translate academic research into practical industrial solutions. His contributions to academia and industry exemplify a dual commitment to theoretical advancements and technological applicability.

Research Focus

Dr. Liu’s research focuses on the design and development of novel polymerization techniques aimed at producing high-performance, specialty elastomer materials. He has made significant breakthroughs in catalytic polymer chemistry, particularly in the following areas:

  1. ⚙️ Rare-earth catalysts: Developed for controlling monomer sequences in cold-resistant and di-end-functionalized rubbers.

  2. 🌀 Anionic ring-opening polymerization: Devised for creating advanced fluorosilicone rubbers with improved thermal and chemical resistance.

  3. 🧲 Lewis acid catalysts: Enabled the selective ylide polymerization of complex structures like C3 polymers.

His work addresses longstanding challenges in structural control, functionality, and performance of elastomeric materials, offering viable solutions for industries ranging from aerospace to biomedical engineering. These contributions are not only academically valuable but also open pathways for commercial-scale polymer manufacturing.

Award and Recognition

Though early in his career, Dr. Liu’s work has already earned significant recognition. He has:

  • Published 38 peer-reviewed articles in top-tier journals such as Angewandte Chemie International Edition, Macromolecules, ACS Macro Letters, and Polymer Chemistry.

  • Achieved an H-index of 16 with over 569 citations according to Web of Science.

  • Filed 11 patents, out of which 4 have been granted, showcasing the patentable quality and industrial relevance of his work.

Publications

📘 Construction of PDMS-crosslinked tread composites that feature high energy-saving and anti-thermal oxidative performances – Composites Part A Applied Science and Manufacturing (2025) – Cited by 1 article.
📘 Aluminum-Mediated Polymerization of Allylic Ylides toward α,ω-Functionalized C3 Polymers with Enhanced Nontraditional Intrinsic Luminescence – Macromolecules (2024) – Cited by 1 article.
📘 Synthesis of α,ω-End Functionalized Polydienes: Allylic-Bearing Heteroleptic Aluminums for Selective Alkylation and Transalkylation in Coordinative Chain Transfer Polymerization – Angewandte Chemie International Edition (2024) – Cited by 4 articles.

 

Vinuta Kamat | Chemistry and Materials Science | Women Researcher Award

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Dr. Vinuta Kamat | Chemistry and Materials Science | Women Researcher Award

Post-doctoral fellow of Jain University of University, India.

Dr. Vinuta Vishnu Kamat is a dedicated and accomplished researcher in the field of chemistry, currently working as a post-doctoral fellow at the Centre for Nano and Material Sciences, Jain University, Bengaluru, India. She has a robust academic background, having completed her Ph.D. in Chemistry at Mangalore University under the guidance of Prof. Boja Poojary. Her dissertation focused on the synthesis, characterization, and biological studies of nitrogen and sulfur-containing heterocycles. Dr. Kamat has a wealth of teaching experience, including three years and eight months of teaching chemistry to B.Sc. students and practical sessions during her doctoral research tenure. She also taught M.Sc. students as a guest faculty at Mangalore University. Her professional competence is demonstrated through her strong teaching skills and her ability to conduct multistep chemical synthesis, purification, and structural determination using various spectroscopic techniques.

 

Professional Profiles:

Education

Dr. Vinuta Kamat is currently pursuing a post-doctoral fellowship at the Centre for Nano and Material Sciences, Jain University, Bengaluru, Karnataka, India, where she has been working since October 2022. Her research focuses on the design and synthesis of nitrogen-containing heterocycles and their biological properties. Prior to this, she completed her Ph.D. in Chemistry at Mangalore University, Mangalagangotri, Karnataka, India, from February 2016 to March 2022. Under the supervision of Prof. Boja Poojary, her dissertation explored the synthesis, characterization, and biological studies of nitrogen and sulfur-containing heterocycles. Dr. Kamat also holds an M.Sc. in Chemistry with a specialization in Medicinal Chemistry, which she obtained from Sri Dharmasthala Manjunatheshwar College, Ujire, Karnataka, India, in 2013, graduating with first-class distinction (70.81%).

Professional Experience

Dr. Vinuta Kamat has a diverse background in teaching and research. She is currently a post-doctoral fellow at the Centre for Nano and Material Sciences, Jain University, Bengaluru, Karnataka, where she has been working since October 2022. Her research focuses on the design and synthesis of nitrogen-containing heterocycles and their biological properties. Before her current role, Dr. Kamat served as a guest faculty member in the Department of Industrial Chemistry at Mangalore University, Karnataka, from April 2022 to October 2022. Here, she taught both theory and practical chemistry courses to B.Sc. and M.Sc. students. Dr. Kamat’s teaching experience spans three years and eight months, during which she taught chemistry theory and practicals to B.Sc. students and conducted practical sessions for M.Sc. students during her doctoral research. She has honed her teaching skills and gained extensive experience in multistep chemical synthesis, purification techniques, and the interpretation of various spectroscopic data. Her professional competence also includes proficiency in MS Office and chemistry software such as ChemDraw and ChemSketch. Dr. Kamat’s contributions to research are evident through her hands-on experience with various instruments and techniques used in her field of study.

Research Interest

Dr. Vinuta Kamat’s research interests lie in several cutting-edge areas of chemistry and material sciences. She is deeply involved in the synthesis and characterization of heterocycles, focusing on their potential biological properties. Her work extends to the synthesis and characterization of metal oxide nanoparticles derived from plant sources, exploring their various applications in environmental remediation and energy. One of her significant interests is in photocatalytic degradation, specifically dye remediation in wastewater, a crucial area for environmental sustainability. Dr. Kamat is also engaged in research related to water splitting and hydrogen evolution, contributing to the development of alternative energy sources. Furthermore, she evaluates antioxidant activity using assays such as DPPH and H2O2 and studies anti-inflammatory properties through protein denaturation methods. Her expertise includes DNA binding studies and hemolytic assays, showcasing her interdisciplinary approach to research. Additionally, Dr. Kamat is proficient in UV and photoluminescence (PL) studies, which are essential for understanding the optical properties of materials. Her diverse research interests reflect her commitment to advancing knowledge in chemistry and its applications to solve real-world problems.

Award and Honors

Dr. Vinuta Vishnu Kamat has been recognized for her exceptional contributions to the field of chemistry with several prestigious awards and honors. She qualified the Graduate Aptitude Test in Engineering (GATE) in 2017, a testament to her proficiency and knowledge in engineering and science. In the same year, she also cleared the Karnataka State Eligibility Test (KSET) for Lecturer/Assistant Professorships, highlighting her academic excellence and teaching capabilities. Her doctoral research was supported by a fellowship from the Karnataka Science and Technology Promotion Society (KSTePS), under the Department of Science and Technology (DST). This fellowship, awarded for her outstanding research potential, enabled her to make significant contributions to her field. Moreover, Dr. Kamat serves as an Editorial Board Member of the American Journal of Heterocyclic Chemistry (AJHC) from May 2023 to May 2025, recognizing her expertise and leadership in heterocyclic chemistry. These accolades reflect her dedication, expertise, and the impact of her research in the scientific community.

Research Skills

Dr. Vinuta Vishnu Kamat possesses a diverse and comprehensive set of research skills, honed through her extensive academic and professional journey in chemistry. She is adept in the synthesis and characterization of heterocycles, showcasing her ability to create and analyze complex chemical compounds. Her proficiency extends to the synthesis and characterization of metal oxide nanoparticles derived from plant sources, indicating her expertise in nanotechnology and green chemistry. Dr. Kamat is skilled in photocatalytic degradation for dye remediation in wastewater, demonstrating her commitment to environmental chemistry and sustainable practices. Her research includes water splitting and hydrogen evolution, highlighting her involvement in alternative energy research. She is experienced in evaluating antioxidant assays using DPPH and H2O2 methods, as well as anti-inflammatory assays through protein denaturation methods. Additionally, she conducts DNA binding studies and hemolytic assays, reflecting her versatility in biochemical research.

Publication

  1. Title: Pyridine- and Thiazole-Based Hydrazides with Promising Anti-inflammatory and Antimicrobial Activities along with Their In Silico Studies
    • Authors: V. Kamat, R. Santosh, B. Poojary, S.P. Nayak, B.K. Kumar
    • Journal: ACS Omega
    • Volume: 5
    • Issue: 39
    • Pages: 25228-25239
    • Year: 2020
    • Citations: 65
  2. Title: Characterization studies of novel series of cobalt (II), nickel (II) and copper (II) complexes: DNA binding and antibacterial activity
    • Authors: V. Adimule, B.C. Yallur, V. Kamat, P.M. Krishna
    • Journal: Journal of Pharmaceutical Investigation
    • Volume: 51
    • Pages: 347-359
    • Year: 2021
    • Citations: 50
  3. Title: Novel pyrazole‐clubbed thiophene derivatives via Gewald synthesis as antibacterial and anti‐inflammatory agents
    • Authors: S.G. Nayak, B. Poojary, V. Kamat
    • Journal: Archiv der Pharmazie
    • Volume: 353
    • Issue: 12
    • Article: 2000103
    • Year: 2020
    • Citations: 34
  4. Title: Synthesis of novel Schiff bases using 2-Amino-5-(3-fluoro-4-methoxyphenyl) thiophene-3-carbonitrile and 1, 3-Disubstituted pyrazole-4-carboxaldehydes derivatives and their …
    • Authors: D. Puthran, B. Poojary, N. Purushotham, N. Harikrishna, S.G. Nayak, V. Kamat
    • Journal: Heliyon
    • Volume: 5
    • Issue: 8
    • Year: 2019
    • Citations: 27
  5. Title: Synthesis, molecular docking, antibacterial, and anti‐inflammatory activities of benzimidazole‐containing tricyclic systems
    • Authors: V. Kamat, B.C. Yallur, B. Poojary, V.B. Patil, S.P. Nayak, P.M. Krishna, S.D. Joshi
    • Journal: Journal of the Chinese Chemical Society
    • Volume: 68
    • Issue: 6
    • Pages: 1055-1066
    • Year: 2021
    • Citations: 12
  6. Title: Novel thiazolidin‐4‐one clubbed thiophene derivatives via Gewald synthesis as anti‐tubercular and anti‐inflammatory agents
    • Authors: S.G. Nayak, B. Poojary, V. Kamat, D. Puthran
    • Journal: Journal of the Chinese Chemical Society
    • Volume: 68
    • Issue: 6
    • Pages: 1116-1127
    • Year: 2021
    • Citations: 10
  7. Title: Synthesis and antibacterial evaluation of pyrazolines carrying (benzyloxy) benzaldehyde moiety
    • Authors: C.H.A. Rajeena, V. Kamat, V.B. Patil, S.P. Nayak, S. Khanapure, D.A. Barretto
    • Journal: Journal of the Iranian Chemical Society
    • Pages: 1-10
    • Year: 2022
    • Citations: 6
  8. Title: In vitro α-amylase and α-glucosidase inhibition study of dihydropyrimidinones synthesized via one-pot Biginelli reaction in the presence of a green catalyst
    • Authors: V. Kamat, D.A. Barretto, B. Poojary, A. Kumar, V.B. Patil, S. Hamzad
    • Journal: Bioorganic Chemistry
    • Volume: 143
    • Article: 107085
    • Year: 2024
    • Citations: 2
  9. Title: Catalytic role in Biginelli reaction: Synthesis and biological property studies of 2‐oxo/thioxo‐1, 2, 3, 4‐tetrahydropyrimidines
    • Authors: V. Kamat, D.S. Reddy, A. Kumar
    • Journal: Archiv der Pharmazie
    • Volume: 356
    • Issue: 6
    • Article: 2300008
    • Year: 2023
    • Citations: 2