Dr. Farid Ahmed | Supramolecular Chemistry | Best Researcher Award

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Dr. Farid Ahmed | Supramolecular Chemistry | Best Researcher Award

Associate Researcher at Shenzhen University | Pakistan

Dr. Farid Ahmed, Ph.D., is a distinguished researcher in organic and supramolecular chemistry with a focus on functional materials, catalysis, and luminescent lanthanide-based systems. He is currently a Research Associate at the Institute for Advanced Study (IAS), Shenzhen University, China, where he continues his postdoctoral research on lanthanide-coordinated crown ether-modified DNA and related luminescent materials. He earned his Ph.D. in Organic Chemistry from the H.E.J. Research Institute of Chemistry, University of Karachi, Pakistan, where his doctoral research involved the synthesis and characterization of thioether-based supramolecules and the evaluation of their photophysical and biological properties under the supervision of Prof. Muhammad Raza Shah. Prior to that, he completed his M.Sc. in Organic Chemistry at the Federal Urdu University of Arts, Science and Technology, Karachi, and a B.Sc. in Pre-Engineering from the University of Karachi. Dr. Ahmed has authored 57 peer-reviewed publications with over 1,153 citations and an h-index of 20 (Scopus), including recent works on synergistic citrazinic acid-functionalized silver nanoparticles for environmental remediation, field-portable colorimetric assays for pharmaceutical detection, and advancements in lanthanide-doped luminescent supramolecular hydrogels. His expertise spans organic synthesis, coordination chemistry, COFs/MOFs, functional nanomaterials, photocatalysts, and energy storage materials. He is proficient in advanced spectroscopic, microscopic, and computational techniques, including NMR, MS, FTIR, TEM, AFM, SEM, and Python/MATLAB-based data analysis. Dr. Ahmed has presented his work at numerous international symposia and received merit-based scholarships during his academic career, reflecting his dedication to innovative chemical research and applications.

Profile: Scopus | ORCID | Google Scholar

Feautured Publications

Ahmed, F., & Xiong, H. (2021). Recent developments in 1, 2, 3-triazole-based chemosensors. Dyes and Pigments, 185, 108905. Cited by 119

Imran, M., Shah, M. R., Ullah, F., Ullah, S., Elhissi, A. M. A., Nawaz, W., Ahmed, F., … (2016). Glycoside-based niosomal nanocarrier for enhanced in-vivo performance of Cefixime. International Journal of Pharmaceutics, 505(1-2), 122–132. Cited by 89

Hussain, M. M., Khan, W. U., Ahmed, F., Wei, Y., & Xiong, H. (2023). Recent developments of Red/NIR carbon dots in biosensing, bioimaging, and tumor theranostics. Chemical Engineering Journal, 465, 143010. Cited by 79

Ahmed, F., Kabir, H., & Xiong, H. (2020). Dual colorimetric sensor for Hg²⁺/Pb²⁺ and an efficient catalyst based on silver nanoparticles mediating by the root extract of Bistorta amplexicaulis. Frontiers in Chemistry, 8, 591958. Cited by 79

ul Ain, N., Anis, I., Ahmed, F., Shah, M. R., Parveen, S., Faizi, S., & Ahmed, S. (2018). Colorimetric detection of amoxicillin based on querecetagetin coated silver nanoparticles. Sensors and Actuators B: Chemical, 265, 617–624. Cited by 67

Liu Feng | Nanocatalytic | Best Researcher Award

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Prof. Liu Feng | Nanocatalytic | Best Researcher Award

Head of Research Office at Yunnan Precious Metals Lab | China

Dr. Liu Feng is a distinguished researcher from China specializing in precious metal nanocatalytic materials, currently affiliated with the Yunnan Precious Metal Laboratory in Kunming City, Yunnan Province. He earned his doctoral degree and has established himself as a leading expert in advanced catalyst design and electrochemical energy conversion. With 87 published documents, 896 total citations, and an h-index of 15 on Scopus, Dr. Liu has made substantial contributions to the field of nanocatalysis and sustainable energy materials. His work primarily focuses on the synthesis, structural modulation, and performance optimization of noble metal-based catalysts for hydrogen evolution and oxygen evolution reactions in water-splitting systems. Among his representative publications are “Size optimization of IrOx nanoparticles synthesized by Br mediation for enhanced PEM water electrolysis” (Molecular Catalysis, 2024), “Atomic Strain Wave-Featured LaRuIr Nanocrystals: Achieving Simultaneous Enhancement of Catalytic Activity and Stability toward Acidic Water Splitting” (Small, 2024), and “Ruddlesden–Popper Sr4Ir3O10 Perovskite: A New Family for Water Splitting Driven by Interlayer Oxygen Migration” (Applied Catalysis B: Environmental, 2024). His additional works in Green Energy & Environment, Journal of Energy Chemistry, and Nano Research further highlight his innovative research on Ru-Ir-Mn oxide systems and bimetallic catalysts for efficient energy conversion. Dr. Liu’s research not only deepens the understanding of nanocatalyst mechanisms but also advances the development of durable and high-performance electrocatalytic materials for clean energy technologies.

Profile: Scopus | ORCID | Google Scholar

Feautured Publications

Zhu, L., Zhang, M., Xu, J., Li, C., Yan, J., Zhou, G., Zhong, W., Hao, T., Song, J., & others. (2022). Single-junction organic solar cells with over 19% efficiency enabled by a refined double-fibril network morphology. Nature Materials, 21(6), 656–663. Cited by: 2,209

Li, C., Zhou, J., Song, J., Xu, J., Zhang, H., Zhang, X., Guo, J., Zhu, L., Wei, D., Han, G., & others. (2021). Non-fullerene acceptors with branched side chains and improved molecular packing to exceed 18% efficiency in organic solar cells. Nature Energy, 6(6), 605–613. Cited by: 1,974

He, Z., Xiao, B., Liu, F., Wu, H., Yang, Y., Xiao, S., Wang, C., Russell, T. P., & Cao, Y. (2015). Single-junction polymer solar cells with high efficiency and photovoltage. Nature Photonics, 9(3), 174–179. Cited by: 1,890

Kan, B., Li, M., Zhang, Q., Liu, F., Wan, X., Wang, Y., Ni, W., Long, G., Yang, X., & others. (2015). A series of simple oligomer-like small molecules based on oligothiophenes for solution-processed solar cells with high efficiency. Journal of the American Chemical Society, 137(11), 3886–3893. Cited by: 918

Zhang, Q., Kan, B., Liu, F., Long, G., Wan, X., Chen, X., Zuo, Y., Ni, W., Zhang, H., & others. (2015). Small-molecule solar cells with efficiency over 9%. Nature Photonics, 9(1), 35–41. Cited by: 901

 

Antoni Mir Pons | Smart Materials | Young Scientist Award

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Mr. Antoni Mir Pons | Smart Materials | Young Scientist Award

University of the Balearic Islands | Spain

Mr. Antoni Mir Pons is a Spanish civil engineer specializing in construction engineering and structural reinforcement, currently serving as a researcher at the University of the Balearic Islands (UIB). He holds a Bachelor’s degree in Industrial Technologies Engineering and Business Administration and Management from the University of Girona. He also earned a Master’s in Industrial Engineering from UIB, where he received the Best Master’s Thesis award. His doctoral research focuses on the effects of semi-cyclic loading on structural reinforcement using iron-based shape-memory alloys (Fe-SMA). Pons has contributed to several international conferences, including SMAR 2024 in Salerno and the 15th fib International PhD Symposium in Budapest, presenting studies on Fe-SMA reinforced concrete structures. His research interests encompass concrete structures and blasting, with a particular emphasis on the application of Fe-SMA for strengthening existing structures. He has been involved in various R&D projects, such as RESTART and CICLO-ESTRUCTURA, focusing on the resilience of concrete infrastructure and the structural effects of cyclic overloads on Fe-SMA reinforced concrete beams. Pons has published articles in peer-reviewed journals, including “Experimental study on semi-cyclic loading effects on Fe-SMA reinforced concrete structures” and “Effects of semi-cyclic loading on the recovery stresses of iron-based shape-memory alloy bars,” both co-authored with Sandra del Río Bonnín, Carlos Ribas, and Antoni Cladera. His Scopus profile indicates 4 documents, 2 citations and an h-index of 1. Additionally, he has teaching experience in laboratory practices for the Structures I course in the Technical Architecture program at UIB. Pons is also active on ResearchGate, where he shares his publications and collaborates with fellow researchers.

Profile: Scopus 

Feautured Publilcations

Mir Pons, A., Del-Río-Bonnín, S., Ruiz-Pinilla, J. G., & Cladera, A. (2025). Experimental study on recovery stress losses in Fe-SMA rebars under semi-cyclic loads considering different activation temperatures and multiple activations. Journal of Structural Engineering, 151(9), 04023109.

Mir Pons, A., Del-Río-Bonnín, S., Ribas, C., & Cladera, A. (2024). Experimental study on semi-cyclic loading effects on Fe-SMA reinforced concrete structures. Materials and Structures, 57(6), 1–16.

Mir Pons, A., Del-Río-Bonnín, S., Ribas, C., & Cladera, A. (2024). Effects of semi-cyclic loading on the recovery stresses of iron-based shape-memory alloy bars. Materials Science and Engineering: A, 859, 144151.

Mir Pons, A., Kustov, B., Ruiz Pinilla, J. G., & Cladera, A. (2024). Characterization of 11-mm Fe-SMA bars used as prestressing reinforcement in concrete structures. Proceedings of the 13th International Conference on Smart Materials and Nanotechnology in Engineering (SMN 2024), 1–8.

Mir Pons, A., Del Río-Bonnín, S., Ribas, C., & Cladera, A. (2024). Effects of semi-cyclic loading on reinforced concrete beams strengthened with iron-based shape-memory alloy bars. Proceedings of the 15th fib International PhD Symposium in Civil Engineering, 1–8.

Manish Kumar | X-ray Diffraction | Young Scientist Award

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Dr. Manish Kumar | X-ray Diffraction | Young Scientist Award

Associate Professor at Delhi University | India

Dr. Manish Kumar, Ph.D. in Inorganic Chemistry from the University of Delhi, is a dedicated researcher specializing in coordination chemistry, organometallic chemistry, and bioinorganic chemistry with significant expertise in the design and synthesis of metal complexes for biological and medicinal applications. His doctoral research focused on the synthesis and characterization of metal complexes derived from quinolone derivatives and heterocyclic ligands, exploring their structural and biological properties. He has authored 145 publications indexed in Scopus, with a total of 1,333 citations from 1,189 documents and an h-index of 19, reflecting both productivity and research impact. His notable works include studies on copper(II) and nickel(II) complexes, nanocomposites, and metallodrug development, contributing to advancements in DNA and protein binding studies, antimicrobial evaluation, and drug delivery systems. Dr. Kumar has co-authored multiple book chapters with international publishers, further demonstrating his contribution to medicinal inorganic chemistry and bioremediation. He has been recognized for his academic and research achievements, including qualifying national-level examinations such as UPSC Chemist, CSIR-UGC NET, and GATE with top rankings. His teaching experience at the University of Delhi as Assistant Professor (Guest) included mentoring postgraduate students and supervising laboratory courses in inorganic chemistry. Beyond his academic output, he has presented at national and international conferences, gaining visibility within the scientific community. With strong laboratory management skills and extensive experience in advanced spectroscopic and electrochemical techniques, Dr. Manish Kumar continues to establish himself as an influential figure in inorganic and bioinorganic chemistry with promising contributions to sustainable and biomedical research.

Profile: Scopus | Google Scholar 

Feautured Publications

Raw, R. S., Kumar, M., & Singh, N. (2013). Security challenges, issues and their solutions for VANET. International Journal of Network Security & Its Applications, 5(5), 95–105. Cited by: 300

Nie, J., Sun, Y., Zhou, Y., Kumar, M., Usman, M., Li, J., Shao, J., Wang, L., … (2020). Bioremediation of water containing pesticides by microalgae: Mechanisms, methods, and prospects for future research. Science of the Total Environment, 707, 136080. Cited by: 297

Kumar, M., Sahu, S. K., Kumar, R., Subuddhi, A., Maji, R. K., Jana, K., Gupta, P., … (2015). MicroRNA let-7 modulates the immune response to Mycobacterium tuberculosis infection via control of A20, an inhibitor of the NF-κB pathway. Cell Host & Microbe, 17(3), 345–356. Cited by: 275

Sinha, A., Gulati, A., Saini, S., Blanc, C., Gupta, A., Gurjar, B. S., Saini, H., … (2014). Prompt plasma exchanges and immunosuppressive treatment improves the outcomes of anti-factor H autoantibody-associated hemolytic uremic syndrome in children. Kidney International, 85(5), 1151–1160. Cited by: 251

Jain, V., Kumar, M., & Chatterji, D. (2006). ppGpp: Stringent response and survival. Journal of Microbiology, 44(1), 1–10. Cited by: 212

Mishra, S., Kumar, R., & Kumar, M. (2023). Use of treated sewage or wastewater as an irrigation water for agricultural purposes—Environmental, health, and economic impacts. Total Environment Research Themes, 6, 100051. Cited by: 182

 

Syeda Naveed Kazmi | Fluid Mechanics | Best Researcher Award

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Syeda Naveed Kazmi | Fluid Mechanics | Best Researcher Award

Lecturer at Mirpur University of Science and Technology | Pakistan

Dr. Syeda Naveed Kazmi is a Senior Lecturer in Mathematics at Mirpur University of Science and Technology (MUST), Pakistan, specializing in heat transfer analysis for peristaltic transport of Newtonian and non-Newtonian nanofluids. She completed her Ph.D. in Mathematics from COMSATS University Islamabad, following an M.Sc. from the University of Azad Jammu & Kashmir. Dr. Kazmi’s research focuses on fluid mechanics, computational fluid dynamics, and nanofluid heat transfer, with a particular emphasis on peristaltic transport mechanisms. She has authored several publications in international journals, including “Entropy generation analysis for hybrid nanofluid mobilized by peristalsis with an inclined magnetic field” in Advances in Mechanical Engineering and “Peristaltic flow under the effects of tilted magnetic field: enhancing heat transfer using graphene nanoparticles” in the International Journal of Modelling and Simulation. Additionally, her work on “Thermal analysis of hybrid nanoliquid containing iron-oxide (Fe3O4) and copper (Cu) nanoparticles in an enclosure” was published in Alexandria Engineering Journal. Her contributions to the field have been recognized internationally, and she continues to advance research in the areas of nanofluid dynamics and heat transfer. Dr. Kazmi’s academic journey reflects a commitment to excellence in research and education in applied mathematics.

Profile: ORCID | Google Scholar

Feautured Publications

Kazmi, S. N., Haq, R. U., & Mekkaoui, T. (2017). Thermal management of water based SWCNTs enclosed in a partially heated trapezoidal cavity via FEM. International Journal of Heat and Mass Transfer, 112, 972–982. Cited by 93.

Qin, H. L., Leng, J., Youssif, B. G. M., Amjad, M. W., Raja, M. A. G., Hussain, M. A., … Kazmi, S. N. (2017). Synthesis and mechanistic studies of curcumin analog‐based oximes as potential anticancer agents. Chemical Biology & Drug Design, 90(3), 443–449. Cited by 47.

Kazmi, S. N., Hussain, A., Rehman, K. U., & Shatanawi, W. (2024). Thermal analysis of hybrid nanoliquid contains iron-oxide (Fe3O4) and copper (Cu) nanoparticles in an enclosure. Alexandria Engineering Journal, 101, 176–185. Cited by 8.

Kazmi, S. N., Abbasi, F. M., & Shehzad, S. A. (2023). An electroosmotic peristaltic flow of graphene-lubrication oil nanofluid through a symmetric channel. Advances in Mechanical Engineering, 15(6), 16878132231177956. Cited by 5.

Kazmi, S. N., Abbasi, F. M., & Iqbal, J. (2024). Double diffusive convection for MHD peristaltic movement of Carreau nanofluid with Hall effects. Proceedings of the Institution of Mechanical Engineers, Part N: Journal of Nanomaterials, Nanoengineering and Nanosystems. Cited by 3.

Yuqing Chen | Electrochemical | Best Researcher Award

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Yuqing Chen | Electrochemical | Best Researcher Award

Associated Professor at Zhejiang Shuren University | China

Dr. Yuqing Chen is currently serves as a Distinguished Associate Researcher at the Institute of Interdisciplinary Sciences, Zhejiang Shuren University. She earned her Ph.D. in Advanced Energy Materials from Hunan University under the supervision of Professor Jilei Liu, a National Young Talent awardee and Vice Dean of the School of Materials Science and Engineering. Prior to this, she completed a joint Master’s program in Electrochemical Technology at Tsinghua University under Professor Xiangming He and obtained a Master’s degree in New Energy Materials and Devices from Wuhan University of Technology under Professor Quanyao Zhu. Her undergraduate studies were in Inorganic Nonmetallic Materials at Wuhan University of Engineering. Dr. Chen’s research focuses on new energy materials and devices, particularly on lithium-ion battery electrolyte design, solvation chemistry, and electrochemical safety. She previously worked as an electrolyte development engineer at Zhejiang Provincial Chemical Research Institute (Sinochem Blue Sky Group), where she designed novel solvent and additive molecules and evaluated battery safety under international standards. She currently leads teaching in university-level chemistry courses, energy chemistry curriculum development, and energy materials research. Dr. Chen has authored 10 SCI-indexed articles with a total impact factor of 150, holds three patents, co-authored one translated book, and has accumulated over 2,500 citations, with an h-index of 19. She has led national projects on high-performance and wide-temperature lithium-ion battery electrolytes and has received multiple honors including the Zhejiang Provincial Intellectual Property Award, the JEC 2021 Best Paper Award, National Scholarship, and other academic and research distinctions.

Profilie: Scopus | ORCID | Google Scholar

Featured Publications

Chen, Y., Kang, Y., Zhao, Y., Wang, L., Liu, J., Li, Y., Liang, Z., He, X., Li, X., et al. (2021). A review of lithium-ion battery safety concerns: The issues, strategies, and testing standards. Journal of Energy Chemistry, 59, 83–99.

Chen, Y., He, Q., Zhao, Y., Zhou, W., Xiao, P., Gao, P., Tavajohi, N., Tu, J., Li, B., et al. (2023). Breaking solvation dominance of ethylene carbonate via molecular charge engineering enables lower temperature battery. Nature Communications, 14(1), 8326.

Chen, Y., He, Q., Mo, Y., Zhou, W., Zhao, Y., Piao, N., Liu, C., Xiao, P., Liu, H., Li, B., et al. (2022). Engineering an insoluble cathode electrolyte interphase enabling high performance NCM811//graphite pouch cell at 60° C. Advanced Energy Materials, 12(33), 2201631.

Kang, Y., Deng, C., Chen, Y., Liu, X., Liang, Z., Li, T., Hu, Q., Zhao, Y. (2020). Binder-free electrodes and their application for Li-ion batteries. Nanoscale Research Letters, 15(1), 112.

Mo, Y., Zhou, W., Wang, K., Xiao, K., Chen, Y., Wang, Z., Tang, P., Xiao, P., Gong, Y., et al. (2023). Engineering electrode/electrolyte interphase chemistry toward high-rate and long-life potassium ion full-cell. ACS Energy Letters, 8(2), 995–1002.

Zhou, W., He, B., Quan, L., Li, R., Chen, Y., Fan, C., Chen, S., Xu, C., Fan, X., Xing, L., et al. (2023). Binder chemistry dependent electrolyte reduction in potassium‐ion batteries: A successive, two‐step reduction way. Advanced Energy Materials, 13(2), 2202874.

 

 

Michele Greque De Morais | Hydrothermal Synthesis | Breakthrough Research Award

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Michele Greque De Morais | Hydrothermal Synthesis | Breakthrough Research Award

Research scholar at Federal University of Rio Grande |  Brazil

Prof. Dr. Michele Greque de Morais is a distinguished scholar at the Federal University of Rio Grande, recognized for her pioneering research in food engineering, biotechnology, and nanobiotechnology. She earned her degrees in Food Science and Engineering at FURG, complemented by international academic experiences at Philipps-Universität Marburg in Germany, the Scripps Institution of Oceanography, and the University of California, San Diego. Her scientific output is extensive, with over 150 peer-reviewed journal articles, 56 book chapters, 58 published books, and more than 200 conference papers. She has also contributed significantly to innovation with 27 patents and the development of 13 technological products. According to Scopus, she has authored 185 indexed works, accumulating 7246 citations with a robust h-index of 47, reflecting the global impact and recognition of her research contributions. Beyond academia, she has led 33 completed and 23 ongoing research projects, partnered with industries in 16 consultancy projects, and played key roles in national and international collaborations focused on sustainable development, microalgae-based bioproducts, and carbon biofixation technologies. Her editorial leadership includes serving as Associate Editor for Bioresource Technology. She has supervised numerous graduate and postgraduate students, shaping future generations of researchers, and has been recognized among the world’s most influential scientists by PLOS Biology. Through her dedication to advancing sustainable bioprocesses, food security, and biotechnology applications, Professor Michele Greque de Morais has established herself as a leading researcher with a profound impact on both scientific knowledge and societal development

Pofile: ScopusORCID | Google Scholar

Featured Publication

De Morais, M. G., & Costa, J. A. V. (2007). Biofixation of carbon dioxide by Spirulina sp. and Scenedesmus obliquus cultivated in a three-stage serial tubular photobioreactor. Journal of Biotechnology, 129(3), 439–445.

De Morais, M. G., Vaz, B. S., De Morais, E. G., & Costa, J. A. V. (2015). Biologically active metabolites synthesized by microalgae. BioMed Research International, 2015(1), 835761.

De Morais, M. G., & Costa, J. A. V. (2007). Isolation and selection of microalgae from coal-fired thermoelectric power plant for biofixation of carbon dioxide. Energy Conversion and Management, 48(7), 2169–2173.

De Morais, M. G., & Costa, J. A. V. (2007). Carbon dioxide fixation by Chlorella kessleri, C. vulgaris, Scenedesmus obliquus and Spirulina sp. cultivated in flasks and vertical tubular photobioreactors. Biotechnology Letters, 29(9), 1349–1352.

Costa, J. A. V., & De Morais, M. G. (2011). The role of biochemical engineering in the production of biofuels from microalgae. Bioresource Technology, 102(1), 2–9.

da Silva Vaz, B., Moreira, J. B., De Morais, M. G., & Costa, J. A. V. (2016). Microalgae as a new source of bioactive compounds in food supplements. Current Opinion in Food Science, 7, 73–77.

Seyed Morteza Mirmohammadi | Thermoplastic Composites | Best Researcher Award-duplicate-1

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Seyed Morteza Mirmohammadi | Thermoplastic Composites | Best Researcher Award

Islamic Azad University |  Iran

Dr. Seyed Morteza Mirmohammadi is an Iranian researcher whose academic and professional trajectory spans textile engineering, polymer-based composites, and industrial systems optimization. He earned his B.Sc. in Textile Engineering from Islamic Azad University, Kashan, followed by an M.Sc. in Industrial Engineering from Islamic Azad University. He is currently pursuing a Ph.D. in Textile Engineering at Islamic Azad University, alongside completing a DBA in Finance from Fanavaran Hakim, Iran, reflecting his multidisciplinary academic profile. His research focuses on advanced materials, particularly polymer-based composites and hybrid woven fabrics, with a strong emphasis on ballistic impact resistance and energy absorption in textile structures. He applies advanced optimization techniques such as Response Surface Methodology (RSM) and Analytic Hierarchy Process (AHP) to develop efficient design and management strategies in engineering systems. Mirmohammadi has presented at numerous national and international conferences, actively contributing to the fields of industrial engineering, composites, and textile technologies, and has published several scholarly works, including notable studies on ballistic impact resistance of hybrid Kevlar/Polypropylene woven fabric composites. He has also been engaged in academic workshops on strategic management and quality systems, aligning his technical expertise with organizational and managerial insights. His professional qualifications include certifications in internal auditing, occupational health and safety, CE marking and risk assessment, as well as marketing management. With advanced skills in research, academic writing, statistical modeling software (SPSS, MATLAB, MINITAB), and quality engineering, he has positioned himself as a versatile scholar and practitioner bridging the gap between materials science, textile engineering, and strategic industrial management.

Pofile: ORCID

Featured Publication

Mirmohammadi, S. M., Shaikhzadeh Najar, S., & Kamali Dolatabadi, M. (2025). Energy absorption of ballistic impact in hybrid Kevlar/Polypropylene woven fabric composites preloaded under simple shear mode: Response surface methodology modeling utilizing a Box–Behnken design. Polymer Composites.

Khadijeh Esmati | Binder Jetting | Best Researcher Award

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Mrs. Khadijeh Esmati | Binder Jetting | Best Researcher Award

Polytechnique Montréal | Canada

Khadijeh Esmati is an accomplished researcher and engineer specializing in stainless steel additive manufacturing, powder metallurgy, welding, and metallurgical process optimization. Currently pursuing her Ph.D. at Polytechnique Montreal, she focuses on the sintering behavior and mechanical properties of stainless steels fabricated by powder bed binder jetting. Her professional journey spans diverse research and engineering roles in Canada and Iran, including significant contributions to Polytechnique Montreal, Amirkabir University of Technology, MANGAN Manufacturing, and TurboTEC. She has developed expertise in heat treatment, mechanical testing, metallography, failure analysis, and nondestructive testing, contributing to industrial and academic advancements. Khadijeh has authored and co-authored peer-reviewed publications in leading journals such as Journal of Materials Research and Technology, Materials Today Communications, and Materials & Design. Her career reflects a strong integration of experimental research, industrial design, and technical leadership, positioning her as a rising figure in materials science and engineering.

Professional Profile

Scopus | Google Scholar

Education

Khadijeh Esmati’s academic background demonstrates a strong foundation in materials engineering and advanced manufacturing. She earned her Bachelor of Science degree in Materials Science and Engineering from Sahand University of Technology, where she studied corrosion and materials behavior in petrochemical applications. She went on to pursue a Master of Science degree in Materials Engineering at Amirkabir University of Technology, Tehran, focusing on welding and brazing of copper-beryllium alloys, where she gained extensive experience in microstructural analysis and mechanical evaluation of diffusion-brazed joints. Currently, she is a Ph.D. student in Mechanical Engineering at Polytechnique Montreal under the supervision of Dr. Étienne Martin. Her doctoral research focuses on additive manufacturing by binder jetting, with a specialization in sintering optimization, anisotropy shrinkage studies, and mechanical property evaluation of stainless steel alloys. Her educational journey has given her a comprehensive understanding of materials characterization, advanced processing, and sustainable metallurgical techniques.

Experience

With extensive research and industrial experience, Khadijeh Esmati has contributed to multiple facets of metallurgical engineering. At Polytechnique Montreal, she has served as a research engineer and doctoral researcher, investigating sintering processes of AlSi10Mg alloys and stainless steels in additive manufacturing. Prior to this, she worked at Amirkabir University of Technology on projects ranging from dual-phase steels and welded structures to turbine blade coatings and corrosion studies. Her industry experience includes her role as Principal Design Engineer at MANGAN Manufacturing, where she oversaw material selection for impellers, steel casting processes, and preparation of welding procedures. At TurboTEC, she contributed to evaluating and improving repair welding for gas turbine components, further expanding her expertise in high-temperature alloys and failure analysis. Across her career, Khadijeh has combined hands-on experimental research with engineering practice, demonstrating her ability to bridge academic innovation with practical industrial applications in metallurgy and materials science.

Awards and Honors

Khadijeh Esmati has been recognized for her academic excellence and contributions to research in welding, powder metallurgy, and additive manufacturing. Her scholarly work has been published in high-quality journals, including Journal of Materials Research and Technology, Materials Today Communications, and Materials & Design. Her early career research on diffusion brazing of copper-beryllium alloys was well received, leading to conference presentations such as the 5th International Conference on Brazing in Nevada. She has also received professional certifications in ultrasonic testing, welding procedure specification, and procedure qualification record preparation, which highlight her technical credibility in both academic and industrial settings. In her doctoral research at Polytechnique Montreal, she has been commended for advancing binder jetting technologies, with her publications reflecting international recognition in additive manufacturing. These achievements, combined with her technical certifications, have positioned her as a rising professional bridging applied research, advanced characterization, and metallurgical engineering innovation.

Research Focus

Khadijeh Esmati’s research focuses on advanced materials processing and characterization, with a particular emphasis on additive manufacturing, binder jetting, and powder metallurgy. Her doctoral work investigates the sintering behavior, anisotropic shrinkage, and mechanical performance of stainless steels fabricated by binder jetting, using advanced characterization tools such as SEM, TEM, EBSD, and dilatometry. She is also engaged in optimizing heat treatment parameters for binder jetted alloys, particularly 17-4 PH stainless steel, to enhance strength, density, and microstructural integrity. Beyond additive manufacturing, her research interests extend to welding metallurgy, diffusion brazing, mechanical testing, and corrosion studies. She has contributed to understanding material failure mechanisms in welded structures, turbine blades, and coatings, providing valuable insights for industrial applications. Her overall research philosophy integrates innovation in material synthesis and processing with detailed structural and mechanical evaluation, aiming to advance sustainable manufacturing practices in metallurgy and mechanical engineering.

Publication top Notes

Study on the microstructure and mechanical properties of diffusion brazing joint of C17200 Copper Beryllium alloy
Year: 2014
Citations: 28

Evaluation of different sintering agents for binder jetting of aluminum alloy
Year: 2023
Citations: 18

Mitigating inherent micro-cracking in laser additively manufactured RENÉ 108 thin-wall components
Year: 2023
Citations: 16

Anisotropic sintering behavior of stainless steel 316L printed by binder jetting additive manufacturing
Year: 2024
Citations: 6

Influence of Temperature and Print Orientation on Anisotropic Sintering in Binder Jet SS316L
Year: 2024
Citations: 2

Conclusion

Khadijeh Esmati is a strong candidate for the Best Researcher Award due to her deep expertise in additive manufacturing, welding, and advanced materials characterization, along with her demonstrated ability to integrate academic research with industrial applications. Her diverse professional experience across both academia and industry highlights her as a resourceful and impactful researcher. With additional focus on sustainability, collaboration, and leadership, she has the potential to emerge as a leading figure in materials engineering. Based on her achievements, she is well-suited for recognition under this award.

Dechao Chen | Electrocatalysts | Best Researcher Award

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Dr. Dechao Chen | Electrocatalysts | Best Researcher Award

Postdoctoral Researcher at Fujian Institute of Research on the Structure of Matter Chinese Academy of Sciences | China

Dr. Dechao Chen is a postdoctoral researcher at the State Key Laboratory of Structural Chemistry, Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences. He has developed expertise in energy chemistry and environmental catalysis, with a strong focus on electrochemical devices and catalytic mechanisms. His academic journey has been marked by rigorous training and innovative contributions to advanced materials and sustainable catalytic systems. Dr. Chen has authored impactful publications in high-impact journals such as Advanced Materials, Nano Letters, Small, and Chemical Engineering Journal. His work explores critical areas including C–N coupling, ammonia synthesis, CO₂ reduction, and hydrogen production. He has also been awarded support from the China Postdoctoral Science Foundation to further develop single-atom catalyst research. Driven by curiosity and dedication, Dr. Chen aims to bridge fundamental science with practical applications to address pressing global energy and environmental challenges.

Professional Profile

Scopus | Google Scholar | ORCID

Education

Dr. Dechao Chen pursued his academic studies with a strong foundation in physics, materials science, and catalysis. He earned his Bachelor of Science degree in Physics and Information Engineering from Minnan Normal University, where he trained under the mentorship of Prof. Zhouan Zhou. His undergraduate work laid the groundwork for his interest in materials chemistry and catalysis. He then advanced his academic career at Hunan University, completing his Ph.D. in Materials Science and Engineering under the guidance of Prof. Yongwen Tan. During his doctoral studies, he focused on nanostructured metal compounds, electrocatalysis, and the development of novel energy conversion materials. His dissertation involved exploring nanoporous two-dimensional materials and electrocatalytic mechanisms for nitrogen reduction and hydrogen evolution. Dr. Chen’s educational journey provided him with extensive expertise in materials synthesis, advanced characterization techniques, and catalytic processes, shaping him into a skilled researcher capable of addressing challenges in sustainable energy.

Experience

Dr. Dechao Chen has gained valuable research experience through academic and institutional roles in materials science and electrochemistry. Currently, he serves as a postdoctoral researcher at the State Key Laboratory of Structural Chemistry, Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences, working under Prof. Lili Han. His postdoctoral research emphasizes surface stress regulation and electrocatalytic CO₂ reduction using single-atom catalysts, supported by funding from the China Postdoctoral Science Foundation. Prior to this, his doctoral research at Hunan University focused on nanoporous two-dimensional compounds with three-dimensional bicontinuous structures, as well as innovative strategies for scalable doping and alloying in transition metal dichalcogenides. He has also conducted collaborative work on gold- and ruthenium-based catalytic systems for nitrogen reduction and hydrogen production. With broad expertise in nanomaterials synthesis, structural analysis, and catalytic applications, Dr. Chen has established himself as a promising researcher in electrochemical energy conversion and environmental catalysis.

Awards and Honors

Dr. Dechao Chen has been recognized for his outstanding contributions to materials science and electrochemical catalysis through significant academic achievements. He received support from the prestigious China Postdoctoral Science Foundation to conduct research on surface stress regulation and CO₂ electroreduction using single-atom catalysts. His publications in highly ranked international journals, including Advanced Materials, Nano Letters, Small, and the Chemical Engineering Journal, serve as testament to his scholarly excellence and innovative contributions. His work has attracted recognition from the global scientific community, highlighting the relevance and originality of his research in energy chemistry and sustainable catalysis. While early in his career, his growing record of publications and funded research demonstrates his potential to achieve further honors and leadership roles in the future. Dr. Chen’s academic trajectory continues to establish him as an emerging figure in his field.

Research Focus

Dr. Dechao Chen’s research focuses on energy chemistry, environmental catalysis, and electrochemical devices. His work spans the development of advanced catalytic systems for C–N coupling, ammonia synthesis, water electrolysis, hydrogen evolution, and CO₂ reduction. He is particularly interested in the design and regulation of single-atom and dual-atom catalysts to optimize catalytic activity and selectivity. His doctoral and postdoctoral studies have also explored the synthesis of nanoporous two-dimensional metal compounds with bicontinuous three-dimensional structures, aiming to enhance surface area, electronic conductivity, and reaction kinetics. Additionally, he investigates the catalytic mechanisms underlying nitrogen reduction and hydrogen production, providing fundamental insights that guide material innovation. By combining advanced materials synthesis, state-of-the-art characterization techniques, and theoretical understanding, his research aims to address urgent global challenges in sustainable energy conversion and environmental remediation. Ultimately, Dr. Chen’s research contributes to advancing green chemistry solutions for next-generation energy technologies.

Publication top Notes

Rational strain engineering of single-atom ruthenium on nanoporous MoS₂ for highly efficient hydrogen evolution
Year: 2021
Citations: 344

Spontaneous Atomic Ruthenium Doping in Mo₂CTX MXene Defects Enhances Electrocatalytic Activity for the Nitrogen Reduction Reaction
Year: 2020
Citations: 320

Identifying Electrocatalytic Sites of the Nanoporous Copper–Ruthenium Alloy for Hydrogen Evolution Reaction in Alkaline Electrolyte
Year: 2020
Citations: 297*

Single-Atom Gold Isolated Onto Nanoporous MoSe₂ for Boosting Electrochemical Nitrogen Reduction
Year: 2022
Citations: 102

Efficient electrosynthesis of formamide from carbon monoxide and nitrite on a Ru-dispersed Cu nanocluster catalyst
Year: 2023
Citations: 82

Scalable synthesis of nanoporous boron for high efficiency ammonia electrosynthesis
Year: 2020
Citations: 41

Conclusion

Dr. Dechao Chen is a highly suitable candidate for the Best Researcher Award. His strong record of publications in top-tier journals, independent research funding, and contributions to the fields of electrocatalysis and sustainable energy place him among the most promising young researchers in materials science. With continued emphasis on industrial translation, leadership development, and innovation beyond academia, he is well-positioned to become a leading figure in his discipline. His profile reflects both scientific excellence and future potential, making him a compelling choice for this recognition.