Swati Gangwar | Chemical Engineering | Women Researcher Award

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Ms. Swati Gangwar | Chemical Engineering | Women Researcher Award

Research scholar from Indian institute of Technology, India

Swati Gangwar is a dedicated research scholar currently pursuing her PhD in Chemical Engineering at the Indian Institute of Technology (IIT), Jammu. With a strong academic foundation marked by a first-class chemical engineering degree from AITH Kanpur and a Master’s degree from Harcourt Butler Technical University (HBTU), Kanpur, she has steadily advanced her expertise in thermal hydraulics and fluid flow. Under the mentorship of P.K. Vijayan, a distinguished expert with extensive experience at BARC, Swati has focused on natural circulation systems, which are critical in energy-efficient and safe passive heat transfer technologies. Her research contributions include experimental, numerical, and analytical studies of thermosyphon heat transport devices, indoor solar cooktops, and passive cooling systems applicable to renewable energy and nuclear safety sectors. Swati’s work has been published in prestigious international journals such as Nuclear Engineering and Design and IEEE Electrification Magazine, demonstrating her ability to contribute novel insights to her field. With ongoing projects and collaborative efforts, she continues to advance research that bridges theoretical understanding and practical innovation in heat transfer mechanisms, positioning herself as a promising leader in chemical engineering research.

Professional Profile

Education

Swati Gangwar completed her Bachelor of Technology (B.Tech) degree in Chemical Engineering from AITH Kanpur in 2016, graduating with first-class honors. She pursued her Master of Technology (M.Tech) in Chemical Engineering at Harcourt Butler Technical University (HBTU), Kanpur, completing it in 2019. Her graduate studies laid a solid foundation in core chemical engineering principles, with a growing interest in thermal systems and fluid mechanics. Currently, she is enrolled in a PhD program at the Indian Institute of Technology Jammu, focusing on heat transfer and fluid flow under the guidance of Professor P.K. Vijayan. The doctoral program enables her to engage deeply in research related to natural circulation loops, thermosyphon heat transport devices, and their applications in sustainable energy systems and nuclear safety. Her education trajectory reflects a consistent focus on advancing her expertise in thermal hydraulics and related engineering challenges, supported by rigorous academic training and research exposure at premier Indian institutions.

Professional Experience

Swati’s professional experience is primarily academic and research-oriented, centered on her PhD studies at IIT Jammu. She has actively contributed to research projects involving thermosyphon heat transport devices and natural circulation systems, focusing on experimental design, numerical modeling, and performance analysis. Her collaboration with her supervisor, Prof. P.K. Vijayan, who has a rich background in nuclear thermal hydraulics and reactor engineering, has enriched her exposure to practical challenges in energy systems design and safety. Swati has also worked on projects related to solar indoor cooktops, a novel application of thermosyphon technology, reflecting her ability to translate research into practical innovations. She has been involved in publishing several peer-reviewed papers in high-impact journals and presenting findings at scientific forums, contributing to the academic community. Although her experience is mainly research-focused, it reflects strong technical skills, teamwork in collaborative environments, and dedication to advancing applied thermal engineering solutions.

Research Interests

Swati’s research interests lie in the field of heat transfer, fluid dynamics, and passive cooling systems. Specifically, she focuses on natural circulation loops (NCLs) and thermosyphon heat transport devices (THTDs), which utilize buoyancy-driven flow to enable efficient heat transfer without mechanical pumps. Her work encompasses both single-phase and two-phase natural circulation systems, with a strong emphasis on stability analysis and flow instabilities. She is particularly interested in developing innovative applications of these passive heat transfer technologies, such as solar indoor cooking devices, passive fuel cooling systems in small modular reactors (SMRs), and sustainable energy solutions like solar space heating. Swati’s research aims to address critical challenges in renewable energy and nuclear safety by optimizing thermal-hydraulic performance and enhancing system stability. Her work bridges theoretical modeling, numerical simulations, and experimental validations to provide comprehensive insights into these systems’ behavior under various boundary conditions, contributing to safer and more efficient energy technologies.

Research Skills

Swati possesses a robust set of research skills combining experimental, analytical, and computational techniques. She is proficient in designing and conducting experiments related to thermosyphon heat transport devices and natural circulation loops, including setup fabrication, instrumentation, and data acquisition. Her skills include numerical modeling and simulation using system codes to predict thermo-hydraulic behavior and flow stability. She has experience in analytical methods for stability criteria development and performance analysis under varying operating conditions. Swati’s ability to integrate experimental data with numerical models allows her to validate and refine theoretical predictions effectively. Additionally, she has strong scientific writing skills, demonstrated through multiple publications in reputed journals. Her research also involves using computational fluid dynamics (CFD) tools for detailed flow analysis. Collaborating with multidisciplinary teams and managing complex research projects further highlights her organizational and teamwork capabilities. Overall, Swati’s research skills position her to make meaningful contributions to passive cooling and heat transfer technologies.

Awards and Honors

Swati Gangwar’s recognition primarily stems from her academic excellence and research contributions during her ongoing PhD. While specific external awards or honors were not explicitly mentioned, her work’s acceptance and publication in high-impact, peer-reviewed journals such as Nuclear Engineering and Design and IEEE Electrification Magazine are significant markers of her research quality and impact. Being mentored by a leading expert in the field, Prof. P.K. Vijayan, also adds to her academic prestige. Her participation in advanced research projects and collaborations, coupled with acceptance of her work in reputed journals, reflects peer recognition within the scientific community. Future recognition may include awards related to innovations in renewable energy or nuclear safety, given the societal relevance of her research areas. Encouragingly, her trajectory and ongoing scholarly output suggest a promising career with potential for further accolades and honors as she continues to contribute to her field.

Conclusion

Swati Gangwar exemplifies a promising young researcher with strong academic foundations, relevant professional experience, and a clear focus on impactful research in thermal hydraulics and fluid flow. Her work on natural circulation loops and thermosyphon devices addresses important challenges in renewable energy and nuclear safety, combining theoretical, numerical, and experimental approaches. With multiple high-quality journal publications and ongoing innovative projects, she is steadily establishing herself as a capable and impactful researcher. To strengthen her profile further, opportunities to demonstrate leadership in research projects, increase engagement with the wider scientific community through conferences, and pursue external funding or patents would be beneficial. Overall, Swati’s dedication and contributions position her well as a deserving candidate for the Women Researcher Award, highlighting her potential as a future leader in engineering research.

Publications Top Notes

  1. Title: Insight on the steady-state performance of single-phase Natural circulation loops
    Year: 2025
    Authors: Swati Gangwar, P. K. Vijayan, Goutam Dutta
    Journal: Nuclear Engineering and Design, Volume 440, 114128

  2. Title: Insights on the instability and stabilizing techniques for natural circulation loops
    Year: 2025
    Authors: P. K. Vijayan, Swati Gangwar, Dev Banitia, U. C. Arunachala, S. Nakul, D. N. Elton, K. Varun
    Journal: Nuclear Engineering and Design, Volume 438, 114017

  3. Title: Intrinsically Safe Thermohydraulic Designs for SMRs: Design advantages and challenges
    Year: 2024
    Authors: P. K. Vijayan, Swati Gangwar
    Journal: IEEE Electrification Magazine, Volume 12, Issue 4, pp. 75–83
    DOI: 10.1109/MELE.2024.3473332

  4. Title: CFD analysis of the steady-state performance of a cooktop integrated Thermosyphon heat transport device with two bends
    Year: 2025
    Authors: Sonu Kumar, Pallippattu Krishnan Vijayan, Swati Gangwar, Satya Sekhar Bhogilla
    Journal: Heat Transfer Engineering Journal (Accepted for publication)

  5. Title: Experimental performance of a novel solar indoor cooktop using THTD
    Year: 2024
    Authors: Swati Gangwar, A. Budakoti, S. S. Bhogilla, G. Dutta, P. K. Vijayan
    Journal: ASTFE Digital Library, Begell House Inc.

Shiqun Wu | Chemical Engineering | Best Researcher Award

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Assoc. Prof. Dr. Shiqun Wu | Chemical Engineering | Best Researcher Award

Associate Professor from East China University of Science and Technology, China

Dr. Shiqun Wu is an accomplished Associate Professor and Master’s Supervisor at the School of Chemistry and Molecular Engineering, East China University of Science and Technology (ECUST). He is a dynamic researcher specializing in photocatalytic materials, with a sharp focus on developing sustainable solutions for energy conversion and environmental remediation. His scientific pursuits contribute significantly to China’s national objectives in carbon neutrality and clean energy innovation. Dr. Wu has authored over 20 SCI-indexed research articles in prestigious journals such as JACS, Angewandte Chemie, Advanced Materials, and Chem, reflecting both the quality and impact of his work. His extensive research has led to over ten patent filings, with two granted, underscoring his efforts to bridge fundamental science with practical application. He has also secured several competitive national and regional grants and actively mentors students, leading them to win top innovation awards. With active roles in editorial boards and professional societies, Dr. Wu continues to shape the research landscape in renewable energy and catalysis. His career reflects a balanced integration of academic excellence, research leadership, and societal relevance, positioning him as an outstanding candidate for recognitions such as the Best Researcher Award.

Professional Profile

Education

Dr. Shiqun Wu has pursued his entire academic career at East China University of Science and Technology (ECUST), a leading institution in applied sciences in China. He began with a Bachelor of Science degree in Applied Chemistry from ECUST, graduating in 2016. During his undergraduate studies, he developed a strong foundation in chemical principles and laboratory techniques, which laid the groundwork for his research trajectory. Following this, he continued at ECUST to pursue a Ph.D. in Applied Chemistry, awarded in 2021 under the mentorship of Professor Jinlong Zhang, a foreign academician of the European Academy of Sciences. His doctoral research focused on the atomic-level design of photocatalytic materials for energy and environmental applications, establishing him as a capable and innovative researcher early in his career. Dr. Wu’s academic training provided him with deep theoretical knowledge and practical expertise in catalysis, nanomaterials, and photochemistry, all essential areas for addressing energy conversion challenges. His educational journey reflects a seamless and accelerated transition from student to scientist, and now to a university-level educator and mentor, equipping him with the pedagogical and technical capabilities to guide the next generation of chemists.

Professional Experience

Dr. Wu’s professional experience has been entirely centered at East China University of Science and Technology, allowing him to develop within a cohesive academic and research environment. After completing his Ph.D. in 2021, he was appointed as a Postdoctoral Fellow at ECUST, where he continued his research under the guidance of Professor Jinlong Zhang. During this three-year postdoctoral phase, he led multiple high-impact research projects, including those funded by the National Natural Science Foundation of China and the China Postdoctoral Science Foundation. His efforts resulted in significant contributions to the field of photocatalysis and material science. In June 2024, Dr. Wu was promoted to the position of Associate Professor in the School of Chemistry and Molecular Engineering. In this role, he not only continues his research but also supervises master’s students, mentors undergraduates, and engages in curriculum development. His progression from student to faculty member within the same institution signifies both loyalty and academic maturity. His career reflects strong leadership, project management, and collaboration with peers and students alike. The continuity and depth of his institutional experience also empower him to influence departmental research direction, making him a valuable asset to ECUST’s academic community.

Research Interests

Dr. Shiqun Wu’s research is primarily focused on the development and engineering of photocatalytic materials aimed at energy conversion and environmental remediation. His work plays a critical role in addressing the global challenges of carbon emissions and sustainable energy. Specifically, his research targets the green transformation of inert molecules such as methane (CH₄), carbon dioxide (CO₂), and nitrogen (N₂), aligning with national and international goals of carbon peaking and neutrality. He investigates atomic-level control of catalyst surface active sites and explores the underlying mechanisms of molecular activation, aiming to optimize efficiency and selectivity in photocatalytic processes. Dr. Wu is especially interested in single-atom catalysts, spin polarization effects, and structure-performance relationships. His interdisciplinary approach blends inorganic chemistry, material science, surface chemistry, and reaction engineering. Through precise material design and performance evaluation, he seeks to advance new-generation photocatalysts with superior conversion efficiencies under solar or visible light. His work contributes to cleaner chemical processes and greener technologies, reinforcing his status as a high-impact researcher. These interests not only contribute to the advancement of academic science but also offer scalable and practical solutions for industrial environmental challenges.

Research Skills

Dr. Wu possesses an advanced skill set that spans synthesis, characterization, and performance evaluation of nanostructured photocatalysts. His expertise includes atomic-level engineering of catalyst surfaces, single-atom dispersion techniques, and the controlled doping of semiconducting materials for enhanced light-driven reactions. He is proficient in a range of experimental methods, including solid-phase synthesis, hydrothermal methods, and sol-gel techniques for preparing oxide-based nanomaterials. Dr. Wu also excels in using advanced characterization tools such as X-ray diffraction (XRD), transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), and Fourier-transform infrared spectroscopy (FTIR) to probe the structural and chemical properties of catalysts. Furthermore, he is skilled in photochemical and photoelectrochemical measurement techniques to assess the catalytic performance, quantum efficiencies, and charge transport properties of photocatalysts. His ability to integrate computational insights with experimental data enhances his understanding of catalytic mechanisms. Dr. Wu’s interdisciplinary approach—spanning materials design, reaction engineering, and mechanism analysis—equips him to develop practical and scalable solutions. His research capabilities are further enriched by experience in leading research teams, writing competitive grant proposals, mentoring graduate students, and disseminating findings through high-impact publications and patents.

Awards and Honors

Dr. Shiqun Wu has received a wide range of prestigious awards and honors throughout his academic and research career, recognizing both his scientific excellence and leadership. He has been the recipient of the Shanghai “Rising Star” Talent Program, the Postdoctoral Innovative Talent Support Program, and the Shanghai “Super Postdoc” Incentive Program. His successful applications to the National Natural Science Foundation of China and the China Postdoctoral Science Foundation reflect his ability to secure highly competitive research funding. Dr. Wu has also demonstrated excellence in mentorship, serving as the first advisor to student teams that won Gold and Bronze Awards at the China International University Student Innovation Competition and the China “Internet+” Innovation and Entrepreneurship Competition. He was a National Finalist in the China Postdoctoral Innovation and Entrepreneurship Competition and was named an Excellent Postdoctoral Researcher in Shanghai in 2021. During his Ph.D., he received the National Graduate Scholarship, the Zhang Jiang Excellent Ph.D. Fellowship, and the third prize in the ACS Graduate Research Achievement Contest. These accolades reflect not only his scientific merit but also his commitment to educational and societal advancement through innovation and collaboration.

Conclusion

Dr. Shiqun Wu represents a new generation of chemists who integrate deep theoretical understanding with experimental rigor to address some of the most pressing challenges in energy and environmental science. His work in photocatalytic materials demonstrates both creativity and precision, aiming to transform inert molecules into valuable chemicals using sustainable, light-driven processes. With over 20 high-impact publications and more than ten patent filings, he has established a strong research profile at an early stage of his career. His contributions extend beyond the lab through effective mentorship, academic leadership, and successful project management. While his international visibility could benefit from further global collaboration and independent project branding, his current trajectory is highly promising. Dr. Wu’s interdisciplinary skills, strategic research focus, and dedication to innovation position him as an outstanding candidate for the Best Researcher Award. His work not only contributes to the scientific community but also aligns with broader environmental and societal goals, reflecting both intellectual merit and practical relevance. As he continues to grow in his academic role, Dr. Wu is expected to make transformative contributions to the field of green chemistry and sustainable catalysis.

Publications Top Notes

  1. Core–Shell MIL-125(Ti)@In2S3 S-Scheme Heterojunction for Boosting CO2 Photoreduction
    Authors: Mazhar Khan, Zeeshan Akmal, Muhammad Tayyab, Seemal Mansoor, Dongni Liu, Junwen Ding, Ziwei Ye, Jinlong Zhang, Shiqun Wu, Lingzhi Wang
    Journal: ACS Applied Materials & Interfaces
    Year: 2025 (May 16)
    DOI: 10.1021/acsami.5c03817

  2. Regulating Atomically‐Precise Pt Sites for Boosting Light‐Driven Dry Reforming of Methane
    Authors: Chengxuan He, Qixin Li, Zhicheng Ye, Lijie Wang, Yalin Gong, Songting Li, Jiaxin Wu, Zhaojun Lu, Shiqun Wu, Jinlong Zhang
    Journal: Angewandte Chemie
    Year: 2024 (Nov 11)
    DOI: 10.1002/ange.202412308

  3. Optimizing Reaction Kinetics and Thermodynamics for Photocatalytic CO2 Reduction through Spin Polarization Manipulation
    Authors: Mingyang Li, Shiqun Wu, Dongni Liu, Zhicheng Ye, Chengxuan He, Jinlong Wang, Xiaoyi Gu, Zehan Zhang, Huizi Li, Jinlong Zhang
    Journal: ACS Catalysis
    Year: 2024 (Sept 20)
    DOI: 10.1021/acscatal.4c03802

  4. Engineering Spatially Adjacent Redox Sites with Synergistic Spin Polarization Effect to Boost Photocatalytic CO2 Methanation
    Authors: Mingyang Li, Shiqun Wu, Dongni Liu, Zhicheng Ye, Lijie Wang, Miao Kan, Ziwei Ye, Mazhar Khan, Jinlong Zhang
    Journal: Journal of the American Chemical Society
    Year: 2024 (June 5)
    DOI: 10.1021/jacs.4c04264

  5. Single‐Atom Alloys Materials for CO2 and CH4 Catalytic Conversion
    Authors: Chengxuan He, Yalin Gong, Songting Li, Jiaxin Wu, Zhaojun Lu, Qixin Li, Lingzhi Wang, Shiqun Wu, Jinlong Zhang
    Journal: Advanced Materials
    Year: 2024 (April)
    DOI: 10.1002/adma.202311628

  6. Boosting CO production from visible-light CO2 photoreduction via defects-induced electronic-structure tuning and reaction-energy optimization on ultrathin carbon nitride
    Authors: J. Li, C. He, J. Wang, X. Gu, Z. Zhang, H. Li, M. Li, L. Wang, S. Wu, J. Zhang
    Journal: Green Chemistry
    Year: 2023
    DOI: 10.1039/d3gc02371k

  7. Combing Hollow Shell Structure and Z-Scheme Heterojunction Construction for Promoting CO2 Photoreduction
    Authors: Z. Deng, J. Cao, S. Hu, S. Wu, M. Xing, J. Zhang
    Journal: Journal of Physical Chemistry C
    Year: 2023
    DOI: 10.1021/acs.jpcc.3c01375

 

Evelyn Faife | Chemical Engineering | Women Researcher Award

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Dr. Evelyn Faife | Chemical Engineering | Women Researcher Award

Doctorate from Cuban Research Institute of Sugarcane Derivatives Research, Cuba

Dr. Evelyn Faife Pérez is a distinguished Chemical Engineer with a career spanning more than two decades in the fields of biotechnology, microbial fermentation, and the sustainable use of agro-industrial residues. She graduated from the Technologic University José Antonio Echevarría (ISPJAE) in 1995 and has since developed extensive experience in academic, research, and project leadership roles across top Cuban and international institutions. Currently serving as a researcher at the Cuban Research Institute of Sugar Cane Derivatives (ICIDCA), Dr. Faife Pérez’s work has centered on biotechnological innovations aimed at transforming waste into valuable products such as microbial oils, carotenoids, and agricultural bioproducts. She has led numerous national and international projects, including those supported by the United Nations Development Programme and intergovernmental initiatives with countries like China. Her international training across countries such as France, India, Japan, China, and Spain reflects her global engagement and commitment to scientific advancement. Dr. Faife Pérez has authored several peer-reviewed papers and contributed chapters in biotechnology-focused books. She has received multiple awards recognizing the scientific and societal impact of her research. Her multifaceted profile demonstrates a deep commitment to sustainable science, making her a valuable contributor to the global research community.

Professional Profile

Education

Dr. Evelyn Faife Pérez holds a strong academic foundation rooted in chemical engineering and advanced biotechnology. She began her academic journey by obtaining a degree in Chemical Engineering from the Technologic University José Antonio Echevarría (ISPJAE) in 1995. Motivated to specialize further, she earned a Master’s degree in Science and Technology of Biotechnological Processes from Havana University in 2001. Her academic path culminated in a Ph.D. in Technical Sciences from her alma mater, ISPJAE, in 2021. This academic trajectory reflects a consistent dedication to scientific development, emphasizing the practical application of bioprocesses in environmental and industrial contexts. Throughout her academic training, Dr. Faife Pérez has cultivated deep expertise in biochemical engineering, microbial fermentation, and sustainable use of biomass. Her doctoral and master’s research provided the framework for her later professional and investigative pursuits in the valorization of agro-industrial waste, development of microbial strains, and bio-based technologies for energy and agriculture. This solid educational background has not only shaped her research competencies but also positioned her as a leader in her field. Her academic progression showcases her enduring commitment to integrating theory with application in solving real-world challenges through biotechnology.

Professional Experience

Dr. Evelyn Faife Pérez’s professional experience is marked by a rich blend of academic instruction, applied research, and project leadership. She began her career as a professor and researcher at the Biotechnology Department of the Pharmacy and Food Faculty at Havana University, where she served from 1995 to 1999. She then transitioned to the Center of Molecular Immunology (CIM) in Havana, contributing a decade (1999–2009) to biotechnological development within the institution’s research division. Since 2009, Dr. Faife Pérez has been a senior researcher in the Biotechnology Directorate at ICIDCA, where she continues to innovate in microbial technology and agro-industrial applications. Her leadership has been pivotal in several prominent projects, including enterprise and intergovernmental collaborations such as those between Cuba and China. Notably, she has directed international projects funded by the UNDP, advancing the use of tolerant yeasts for high-value additives. Dr. Faife Pérez’s professional journey reflects a commitment to converting scientific research into viable industrial and agricultural solutions. Her role at ICIDCA positions her at the intersection of academic rigor and applied science, enabling the transfer of laboratory innovations into scalable technologies. Her experience is further enhanced by international training in countries such as France, India, Japan, and China.

Research Interests

Dr. Evelyn Faife Pérez’s research interests lie at the intersection of biotechnology, sustainable development, and microbial engineering. Her work predominantly focuses on the biotechnological conversion of agro-industrial residues—particularly sugarcane derivatives—into valuable bio-products such as microbial oils, carotenoids, and enzymes. She is highly engaged in developing bioprocesses that utilize efficient microorganisms, especially yeasts like Rhodotorula toruloides, for biofuel production, animal feed, and agricultural applications. Her interest extends to microbial tolerance studies, fermentation technologies, and the use of renewable substrates like vinasse and raw glycerol in industrial bioprocessing. Additionally, she is involved in solvent extraction techniques for natural product isolation, particularly applying group contribution methods and solubility theory. Dr. Faife Pérez is also interested in enhancing sustainable waste management by introducing microbial treatments that reduce environmental impact and add value to waste streams. These research interests reflect a profound commitment to bioeconomic principles and environmental stewardship, reinforcing her contribution to both academic science and real-world sustainability. Her focus on interdisciplinary and applied research ensures that her findings address current industrial and environmental challenges while offering innovative, cost-effective solutions for the future of biotechnology and renewable energy sectors.

Research Skills

Dr. Evelyn Faife Pérez has developed a comprehensive skill set in biotechnological research, underpinned by years of practical and academic experience. Her core competencies include microbial cultivation, fermentation technologies, enzymatic analysis, and biomass valorization. She is adept at isolating and optimizing microbial strains, particularly oleaginous yeasts such as Rhodotorula toruloides, for bio-production processes. Additionally, she has expertise in handling inhibitory compounds during fermentation, selecting tolerant mutants, and improving product yields. Her technical knowledge extends to solvent selection methodologies using Hansen Solubility Parameters and Group Contribution Models, enhancing her capabilities in the extraction and purification of bioactive compounds. Dr. Faife Pérez also demonstrates strong project management skills, having led national and international research initiatives from conception to implementation. She is experienced in cross-cultural collaborations and the integration of renewable energy concepts into biotechnological workflows. Her international training has expanded her methodological toolkit, incorporating technologies and best practices from global centers of excellence. She is proficient in scientific writing and communication, contributing to journals, book chapters, and symposiums. Collectively, her research skills enable her to conduct high-impact studies that integrate innovation, sustainability, and practical application, reinforcing her position as a capable and forward-thinking biotechnologist.

Awards and Honors

Dr. Evelyn Faife Pérez has been the recipient of several awards recognizing her contributions to science, particularly in biotechnology and sustainable bioprocess development. In 2017 and 2019, she received the Award to the Best Scientific Work from AZCUBA, Cuba’s leading sugar industry organization. These awards were granted for her innovative research on the fermentation processes using microbial oils from vinasse and glycerol, as well as for her work on selecting microbial strains tolerant to inhibitors derived from sugarcane bagasse hydrolysis. In 2019, she was also honored with the ICIDCA Scientific Award for her pivotal study on identifying cyclic lipopeptides from Bacillus amyloliquefaciens with antifungal activity. These recognitions underscore the scientific and practical value of her research, particularly its relevance to Cuba’s sugar industry and agricultural sectors. Her achievements highlight her capability to bridge scientific inquiry with industrial application, making her a valuable contributor to national development and international scientific progress. The consistent recognition of her work not only validates the impact of her research but also reflects her leadership in advancing biotechnological innovations that are sustainable, scalable, and economically beneficial.

Conclusion

Dr. Evelyn Faife Pérez embodies a dynamic and impactful profile in the realm of biotechnological research, with notable contributions in microbial fermentation, renewable resource utilization, and sustainable agriculture. Her extensive educational background and multifaceted professional experience allow her to approach scientific problems with both theoretical depth and practical insight. As a leader in research projects and an active contributor to academic literature, she has shown a consistent ability to translate complex scientific ideas into applicable technologies. Her work aligns with global priorities such as sustainability, waste reduction, and green energy, making her research both timely and socially relevant. The international recognition of her work through awards and scholarly collaborations further reinforces her role as a respected and influential scientist. By continuing to innovate in areas like microbial oil production, yeast biotechnology, and agro-industrial waste treatment, Dr. Faife Pérez remains at the forefront of applied biosciences. Her career stands as a testament to the value of science in addressing environmental challenges and improving industrial processes. With her continued dedication, she is well-positioned to contribute to future advancements in sustainable biotechnology on both a national and global scale.

Publications Top Notes

  1. Use of wastewaters from ethanol distilleries and raw glycerol for microbial oils production from Rhodsporidium toruloides

    • Authors: Faife E., Ochoa N., Dehua Liu et al.

    • Year: 2025 (Accepted)

  2. Current Advances in Carotenoid Production by Rhodotorula sp.

    • Authors: Ochoa N., Alonso D., Pacios S., García A., Ramos R., Faife E., et al.

    • Year: 2024

    • Journal: Fermentation, 10(4), 190

  3. Use of Group Contribution Methods, Hansen’s Theory of Solubility and Microsoft Excel in the Selection of Solvents for the Extraction of Natural Products

    • Authors: Días M., Faife E.

    • Year: 2023 (Preprint)

  4. Rhodotorula toruloides as a biofactory of carotenoids, lipids and enzymes. Microbial fermentations in nature and as designed processes

    • Authors: Ochoa N., Alonso D., Faife E., et al.

    • Year: 2023

    • Book Chapter: Microbial Fermentations in Nature and as Designed Processes, Chapter 2

    • DOI link

  5. Use of efficient microorganisms (ME) as an alternative for the treatment of residuals (Review)

    • Authors: Faife-Pérez E., Roget-Guevara D., Fandiño C.A., et al.

    • Year: 2018

    • Journal: ICIDCA Sobre los derivados de la caña de azúcar, Vol. 52(3)

    • ISSN: 2410-8529

  6. Selection and evaluation of Rhodosporidium toruloides mutants tolerant to inhibitors generated from the acid hydrolysis of sugarcane bagasse

    • Authors: Ochoa Viñals N., Faife E., Michelena G.

    • Year: 2017

    • Type: Master’s Thesis, University of Havana (U.H.)

  7. Use of wastewaters from ethanol distilleries and glycerol mixtures for microbial oils production

    • Authors: Faife E., Martínez A., Martínez Y., et al.

    • Year: 2016

    • Journal: American Journal of Bioscience and Bioengineering, 4(4): 41-48

    • DOI: 10.11648/j.bio.20160404.11

  8. Evaluation of the growth of the oleaginous yeast R. toruloides in the presence of sugarcane bagasse hydrolyzate inhibitors

    • Authors: Ochoa-Viñals N., Faife-Perez E., Du W., Zhao Xuebing, Liu Dehua

    • Year: 2016

    • Journal: ICIDCA Sobre los derivados de la caña de azúcar, Vol. 50(3), pp. 50-53

    • ISSN: 0138-6204

Meijin Guo | Chemical Engineering | Best Researcher Award

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Mr. Meijin Guo | Chemical Engineering | Best Researcher Award

Professor at East china university of science & technology, China

Professor Meijin Guo is a renowned scholar in the field of bioengineering, currently serving as a full professor at the School of Bioengineering, East China University of Science and Technology (ECUST). With over two decades of academic and research experience, she has made significant contributions to microbial fermentation, stem cell bioprocessing, and metabolic regulation. Professor Guo holds a Ph.D. in Biochemical Engineering from ECUST, a Master’s degree in Microbiology from Guizhou University, and a Bachelor’s degree in Agronomy from Jiangxi Agricultural University. Her research has been instrumental in advancing technologies related to the large-scale production of mesenchymal stem cells, as well as in understanding the metabolic mechanisms of microbial synthesis under stress conditions. As a leading figure in national scientific projects, she has played key roles in high-impact studies supported by the National Natural Science Foundation of China and the Chinese Academy of Sciences. Professor Guo has authored numerous influential papers and serves as a co-corresponding author on multiple internationally recognized publications. Her work has also earned her prestigious national and provincial awards in scientific advancement. She is deeply committed to integrating engineering principles with biotechnology to solve real-world problems, bridge academic research and industrial applications, and foster innovation in biosciences.

Professional Profile

Education

Meijin Guo’s academic foundation reflects a strong interdisciplinary background that underpins her distinguished research career in bioengineering. She earned her Ph.D. in Biochemical Engineering from East China University of Science and Technology (1998–2001), where she began specializing in microbial metabolism and fermentation technologies. Her doctoral research laid the groundwork for her later contributions to bioreactor design and metabolic regulation. Prior to that, she obtained a Master’s degree in Microbiology from Guizhou University (1995–1998), focusing on microbial physiology and enzyme production. This period shaped her understanding of the biological and functional diversity of microorganisms, which remains central to her work. She started her academic journey with a Bachelor’s degree in Agronomy from Jiangxi Agricultural University (1988–1992), where she gained a solid grasp of plant and soil sciences, giving her early insight into life sciences from an agricultural perspective. Her seamless transition across agronomy, microbiology, and biochemical engineering highlights her multidisciplinary approach and commitment to addressing challenges across the life science spectrum. With this broad educational foundation, Professor Guo has cultivated a research style that bridges fundamental biology and practical engineering solutions, making her uniquely positioned to lead innovative research projects in the rapidly evolving field of biological engineering.

Professional Experience

Professor Meijin Guo has built a robust professional career centered on academic research and biotechnological innovation. She currently holds a professorship in the School of Bioengineering at East China University of Science and Technology (ECUST), a role she has occupied since October 2010. In this position, she leads multiple research projects, mentors graduate students, and contributes to academic development within the institution. Prior to this role, she served as an associate professor at ECUST from November 2005 to September 2010, furthering her work in fermentation optimization and bioreactor engineering. Between October 2004 and October 2005, she expanded her academic horizons with a research stint at the University of Strathclyde in the United Kingdom, where she engaged in international collaboration and broadened her scientific perspectives. From July 2001 to September 2004, she worked as an assistant researcher at the Biotechnology Center of Jiangxi Agricultural University, initiating her professional research journey with a focus on microbial technology and fermentation systems. Throughout her career, Professor Guo has consistently demonstrated a commitment to translating scientific knowledge into scalable biotechnological applications, earning respect in academic and industry circles alike. Her diverse experience underscores her capabilities as a leader in bioengineering and applied life sciences.

Research Interest

Professor Meijin Guo’s research interests lie at the intersection of microbial biotechnology, biochemical engineering, and stem cell bioprocessing. Her work primarily focuses on the development and scale-up of bioreactors for the mass production of stem cells, with a particular emphasis on mesenchymal stem cells derived from human embryonic and umbilical cord sources. She is passionate about optimizing bioreactor environments to preserve stem cell activity and function while enabling reproducibility at industrial scales. Another major aspect of her research involves exploring the stress-induced metabolic regulation of microbial systems, especially in vitamin B12 biosynthesis by Pseudomonas denitrificans under oxygen-limited conditions. Her research integrates omics technologies and computational modeling, including computational fluid dynamics, to understand and control bioprocess variables. Additionally, she has shown a keen interest in bioprocess parameter optimization, cell metabolism, and organoid-based toxicity screening platforms. This interdisciplinary approach allows her to develop innovative solutions for therapeutic applications and industrial biotechnology. Through collaboration with clinicians and bioengineers, she aims to bridge the gap between laboratory research and clinical or commercial implementation. Her ongoing projects reflect her commitment to applying systems biology and process engineering tools to improve biomanufacturing practices and advance personalized medicine through scalable and efficient bioprocesses.

Research Skills

Professor Meijin Guo brings an exceptional suite of research skills that reflect her deep engagement with modern bioengineering methodologies. She is highly experienced in bioreactor design and scale-up, with specific expertise in stirred suspension systems for stem cell culture. Her ability to integrate computational fluid dynamics (CFD) modeling into bioprocess development enables predictive design and real-time optimization of large-scale cell cultures. She is also proficient in microbial metabolic engineering, particularly for vitamin B12 biosynthesis under stress conditions, leveraging molecular biology tools to dissect and manipulate key biosynthetic pathways. In addition, she employs high-throughput screening technologies and label-free imaging platforms for compound toxicity studies using organoids, demonstrating her strength in cutting-edge cellular analysis techniques. Professor Guo also excels in experimental planning, data analysis, and scientific communication, often serving as co-corresponding author on high-impact journal publications. She is adept at leading multidisciplinary research teams and managing complex, large-scale projects funded by national and institutional grants. Her collaborative mindset and technical versatility enable her to adapt to rapidly evolving research challenges and contribute meaningfully to both fundamental research and translational applications. Through her skills, she not only drives scientific discovery but also enhances the reproducibility and scalability of biotechnological processes.

Awards and Honors

Professor Meijin Guo has received numerous prestigious awards in recognition of her scientific contributions to biochemical engineering and biotechnology. In 2002, she was part of a research team that won the State Scientific and Technological Progress Award (Second Class) from the State Council of China for their work on parameter-driven optimization and scale-up techniques in fermentation bioreactors. She was again honored in 2011 with another Second-Class National Award for Scientific and Technological Progress, recognizing her work in developing fermentation optimization technologies based on physiological and process information analysis. These accolades underscore her leadership in bridging theoretical and practical aspects of bioprocess engineering. Additionally, in 2003, she received a First-Class Provincial and Ministerial Science and Technology Progress Award from the Shanghai Municipal Government for her contributions to the production of thermostable phytase enzymes and gene identification related to high-activity phytase, highlighting her role in enzyme biotechnology. These awards, granted at both national and regional levels, reflect her sustained impact in the scientific community and her capacity to drive innovation in applied life sciences. Professor Guo’s honors not only recognize past achievements but also affirm her ongoing role as a pioneer in the field of biological engineering in China.

Conclusion

Professor Meijin Guo stands as a leading figure in China’s bioengineering landscape, with a career that combines scientific depth, technical innovation, and a collaborative spirit. Her academic journey from agronomy to microbiology and biochemical engineering has shaped a uniquely interdisciplinary research profile. Over the years, she has played a key role in advancing scalable bioprocessing systems, metabolic regulation studies, and the integration of computational modeling with experimental biology. Her extensive publication record and multiple research grants—both national and institutional—demonstrate her status as a trusted and capable leader in scientific inquiry. Through her work on stem cell bioreactors and vitamin biosynthesis, she has made critical contributions to biomanufacturing and therapeutic development. The national recognition she has received, including two prestigious State Scientific and Technological Progress Awards, affirms the real-world impact of her research. As science and technology continue to evolve, Professor Guo remains committed to mentoring young researchers, fostering cross-disciplinary partnerships, and applying engineering principles to solve complex biological challenges. Her continued leadership ensures that the bridge between scientific research and industrial innovation remains strong, timely, and impactful. In every aspect of her professional life, she embodies the values of rigor, creativity, and purpose-driven science.

Publications Top Notes

  1. Title: De Novo synthesis of selenium-doped CeO2@Fe3O4 nanoparticles for improving secondary metabolite biosynthesis in Carthamus tinctorius cell suspension culture
    Authors: K. Ashraf, Z. Liu, Q.U. Zaman, … M. Guo, A. Mohsin
    Year: 2025

  2. Title: Scalable Matrigel-Free Suspension Culture for Generating High-Quality Human Liver Ductal Organoids
    Authors: S. Gong, K. He, … Z. Yang, M. Guo
    Year: 2025

  3. Title: Temporal dynamics of stress response in Halomonas elongata to NaCl shock: physiological, metabolomic, and transcriptomic insights
    Authors: J. Yu, Y. Zhang, H. Liu, … M. Guo, Z. Wang
    Year: 2024
    Citations: 7

  4. Title: Uncovering impaired mitochondrial and lysosomal function in adipose-derived stem cells from obese individuals with altered biological activity
    Authors: B. Wang, G. Zhang, Y. Hu, … M. Guo, H. Xu
    Year: 2024
    Citations: 4

  5. Title: Sustainable biosynthesis of lycopene by using evolutionary adaptive recombinant Escherichia coli from orange peel waste
    Authors: M. H. Hussain, S. Sajid, M. Martuscelli, … M. Guo, A. Mohsin
    Year: 2024
    Citations: 2

  6. Title: A novel perspective on the role of long non-coding RNAs in regulating polyphenols biosynthesis in methyl jasmonate-treated Siraitia grosvenorii suspension cells
    Authors: Z. Liu, M. Guo (Meihui), A. Mohsin, … Z. Wang, M. Guo (Meijin)
    Year: 2024

  7. Title: A machine learning-based approach for improving plasmid DNA production in Escherichia coli fed-batch fermentations
    Authors: Z. Xu, X. Zhu, A. Mohsin, … M. Guo, G. Wang
    Year: 2024
    Citations: 3

  8. Title: Uncovering the Role of Hydroxycinnamoyl Transferase in Boosting Chlorogenic Acid Accumulation in Carthamus tinctorius Cells under Methyl Jasmonate Elicitation
    Authors: Z. Liu, X. Zhu, A. Mohsin, … Y. Zhuang, M. Guo
    Year: 2024
    Citations: 2

  9. Title: Research on the Transient Expression of a Novel PCV2 Capsid Fusion Protein in HEK293F Cells
    Authors: Q. Luo, Y. Peng, M. Ali (Mohsin), Y. Zhuang, M. Guo
    Year: 2024

  10. Title: Polyphenol oxidase inhibition by Saccharomyces cerevisiae extracts: A promising approach to prevent enzymatic browning
    Authors: Z. Liu, H. Ding, M. Martuscelli, … M. Guo, Z. Wang
    Year: 2024
    Citations: 5

Kowsar Rezvanian | Chemical Engineering | Best Researcher Award

Published on by Shen Awards

Ms. Kowsar Rezvanian | Chemical Engineering | Best Researcher Award

Graduate Research Assistant (GRA) from Tuskegee University, United States

Kowsar Rezvanian is an accomplished researcher with a strong academic background and a focus on sustainability and material science. She holds a Ph.D. in Materials Science and Engineering from Tuskegee University, where she achieved a perfect GPA of 4.0, reflecting her academic excellence and dedication. Kowsar’s research addresses critical environmental challenges, particularly in the fields of polymer science, food packaging, and wastewater treatment. Her work involves innovative methods such as upcycling multilayer plastic films and optimizing materials for food preservation, contributing significantly to both scientific knowledge and environmental sustainability. In addition to her academic accomplishments, Kowsar has presented her research at various international conferences, demonstrating her global perspective on the importance of sustainable practices. Through her publications in high-impact journals, she has made valuable contributions to her field. Kowsar’s leadership roles in research teams and her involvement in industry-related projects underscore her commitment to advancing scientific knowledge and providing real-world solutions.

Professional Profile

Education

Kowsar Rezvanian has a solid educational foundation, having earned a Ph.D. in Materials Science and Engineering from Tuskegee University, where she maintained a perfect GPA of 4.0. She also holds an M.Sc. in Chemical Engineering from the same institution, where she achieved an impressive GPA of 3.85/4. Her academic journey began at Tehran Polytechnic, where she completed her BSc in Chemical Engineering with a GPA of 3.10/4. Her exceptional academic performance throughout her studies reflects her passion for research and learning. During her doctoral studies, Kowsar gained expertise in materials science, particularly focusing on sustainability in polymer processing and environmental conservation. She continuously sought to integrate theory with practical solutions, which shaped her ability to develop meaningful and impactful research. Her education laid the groundwork for her research on innovative recycling processes and the optimization of materials for real-world applications, such as food packaging and wastewater treatment, which are central themes of her current work.

Professional Experience

Kowsar Rezvanian has gained extensive professional experience as a Graduate Research Assistant at Tuskegee University, where she has worked since 2021. In this role, she has been responsible for data collection and storage, conducting data analysis, managing project inventories, and developing new research practices and tools. Her work at Tuskegee University has allowed her to further her research in sustainability and materials science, particularly in the optimization of polymer films for food packaging and the upcycling of multilayer plastic films for industrial applications. In addition to her academic role, Kowsar also served as a member of the board of directors at Arka Company, where she contributed to decision-making and project management between 2019 and 2021. Her prior experience as a Heat Transfer Teaching Assistant at Tuskegee University also showcases her capability to communicate complex concepts to students and assist in the development of curriculum materials. This diverse professional experience has provided Kowsar with a comprehensive understanding of both the academic and industrial aspects of materials science and engineering.

Research Interests

Kowsar Rezvanian’s research interests are focused on addressing global challenges through sustainable material science and engineering. Her work primarily revolves around the development of innovative recycling techniques for multilayer plastic films and optimizing materials for food packaging. She is passionate about advancing environmental sustainability through the upcycling of plastic waste into nanocomposite materials, promoting a circular economy. In her research on food packaging, Kowsar focuses on optimizing the thickness and ethylene content of poly(ethylene vinyl alcohol) (EVOH) films to improve their mechanical and thermal properties, ultimately enhancing food preservation and reducing waste. Another key area of her research is wastewater treatment, specifically using photocatalytic processes to treat refinery wastewater and reduce chemical oxygen demand (COD). Kowsar’s research also explores the scale-up of food product manufacturing processes, ensuring that scientific innovations can be translated to large-scale, industrial applications. Through these efforts, Kowsar aims to make significant contributions to the sustainability of materials used in packaging, food preservation, and environmental conservation.

Research Skills

Kowsar Rezvanian possesses a wide range of advanced research skills that support her innovative work in materials science and environmental sustainability. She is proficient in various software tools and programming languages such as Maestro Materials, Aspen HYSYS, MATLAB, and Python, which she uses to model, optimize, and analyze material properties and processes. Kowsar is skilled in material characterization techniques, including Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM), Differential Scanning Calorimetry (DSC), Thermogravimetric Analysis (TGA), X-Ray Diffraction (XRD), and Fourier Transform Infrared Spectroscopy (FTIR), which she uses to evaluate the properties of different materials, including plastics and polymers. Her hands-on skills also include utilizing equipment such as CNC machines, 3D printers, water jet cutters, and mechanical testing devices for the fabrication and testing of materials. Kowsar’s expertise in design software such as Fusion 360 and Prusa Slicer further complements her research in developing new material solutions for applications like 3D printing and packaging. These technical skills enable her to approach complex challenges with a multidisciplinary and innovative perspective.

Awards and Honors

Kowsar Rezvanian has received several prestigious awards and honors in recognition of her outstanding academic and research achievements. She was the recipient of the GRSP Scholarship for the 2024-2025 academic year, which highlights her potential for continued academic and professional growth in the field of materials science and engineering. Additionally, Kowsar was honored as the IFT Product Development Winner in 2022, an award that recognizes her contributions to food science and packaging technologies. These accolades are a testament to her dedication to advancing knowledge in her field and to the quality of her research. Kowsar’s recognition in both academic and professional circles reflects her ability to produce work that is not only innovative but also impactful. As she continues her research, she is likely to receive further recognition for her efforts to develop sustainable materials and solutions that address pressing global challenges in environmental conservation and industrial applications.

Conclusion

Kowsar Rezvanian is a dedicated and highly skilled researcher whose work in materials science and engineering has made a significant impact on sustainability and environmental conservation. With a strong academic foundation, outstanding research achievements, and a focus on real-world applications, Kowsar has demonstrated exceptional potential for advancing both scientific knowledge and industrial practices. Her ongoing research on upcycling plastic waste, optimizing food packaging, and improving wastewater treatment showcases her commitment to addressing global challenges through innovation. While her professional experience and technical expertise position her for continued success, there are opportunities for Kowsar to further enhance her profile by expanding her leadership roles, strengthening industry collaborations, and exploring additional interdisciplinary research areas. As a result, Kowsar is poised to make even more significant contributions to the field and is well-deserving of recognition for her achievements.

Publications Top Notes

  1. Title: A review on sweet potato syrup production process: Effective parameters and syrup properties
    Authors: K Rezvanian, S Jafarinejad, AC Bovell-Benjamin
    Year: 2023
    Citations: 5

  2. Title: Optimizing Process Variables and Type in a Sweet Potato Starch Syrup: A Response Surface Methodology Approach
    Author: K Rezvanian
    Institution: Tuskegee University
    Year: 2023
    Citations: 5

  3. Title: Mathematical Modeling and Optimization of Poly (Ethylene Vinyl Alcohol) Film Thickness and Ethylene Composition Based on I‐Optimal Design
    Authors: K Rezvanian, R Panickar, F Soso, V Rangari
    Journal: Journal of Applied Polymer Science
    Volume: e56827
    Year: 2025

  4. Title: Cover Image, Volume 142, Issue 18
    Authors: K Rezvanian, R Panickar, F Soso, V Rangari
    Journal: Journal of Applied Polymer Science
    Volume: 142 (18), e54197
    Year: 2025

  5. Title: Innovative Manufacturing and Recycling Approaches for Multilayer Polymer Packaging: A Comprehensive Review
    Authors: K Rezvanian, HT Shahan, D Ghofrani, V Rangari
    Journal: Polymer-Plastics Technology and Materials
    Year: 2025

  6. Title: Response Surface Methodological Approach for Scaling Up an Enzymatic Production of Sweet Potato Starch Syrup
    Authors: K Rezvanian, PN Gichuhi, AC Bovell-Benjamin
    Journal: Journal of Food Processing and Preservation
    Volume: 2025 (1), 8870506
    Year: 2025

  7. Title: A Review on Sweet Potato Syrup Production Process: Effective Parameters and Syrup Properties
    Authors: K Rezvanian, S Jafarinejad, AC Bovell-Benjamin
    Journal: Processes
    Volume: 11, 3280
    Year: 2023

  8. Title: Recent Advances in the Fabrication of High-Performance Forward Osmosis Membranes to Concentrate Ammonium in Wastewater
    Authors: K Rezvanian, S Jafarinejad
    Conference: Euro-Mediterranean Conference for Environmental Integration
    Pages: 83-84
    Year: 2022

Safdar Ali Amur | Chemical Engineering | Best Researcher Award

Published on by Shen Awards

Mr. Safdar Ali Amur | Chemical Engineering | Best Researcher Award

Beijing University of Chemical Technology, China

Safdar Ali Amur is a dedicated researcher in the fields of chemical engineering, biochemistry, and microbiology. With a strong academic foundation and international research exposure, he has contributed significantly to biomedical applications, focusing on metal-organic frameworks for antibacterial applications. He is currently pursuing a Ph.D. in Chemical Engineering & Technology at Beijing University of Chemical Technology, China. His expertise spans analytical chemistry, molecular modeling, and microbiological testing, making him a valuable contributor to scientific advancements. In addition to his research pursuits, he has experience in teaching, administrative roles, and laboratory management. His technical proficiency includes advanced scientific software and instrumentation techniques, supporting his innovative approach to scientific inquiries. With multiple research publications indexed in Google Scholar, ORCID, and Web of Science, Safdar demonstrates an ongoing commitment to expanding knowledge in his field. His background in biochemistry, microbiology, and vaccine supply management through WHO also highlights his ability to work in interdisciplinary research environments. Despite his achievements, he continues to seek opportunities for collaborative research and professional growth. His aspirations include furthering biomedical applications through nanotechnology-based innovations, aiming to bridge fundamental research with practical applications in healthcare and industry.

Professional Profile

Education

Safdar Ali Amur has pursued a rigorous academic journey that reflects his dedication to research and scientific exploration. Currently, he is a Ph.D. candidate in Chemical Engineering & Technology at Beijing University of Chemical Technology, China, where he is working on bioactive material encapsulation for antibacterial applications. His Ph.D. research integrates chemical sciences, biochemistry, and biomedical engineering, showcasing interdisciplinary expertise. Before his doctoral studies, he earned a Master of Philosophy (M.Phil.) in Biochemistry from the University of Sindh, Pakistan. His thesis focused on epidemiology and serum lipid alterations in laryngeal and pharyngeal cancer patients, contributing to understanding cancer biomarkers. His bachelor’s degree in Biochemistry, also from the University of Sindh, provided him with a solid foundation in biological sciences, chemistry, and analytical techniques. In addition to formal education, he has completed various certifications and internships, including analytical instrumentation training at the Pakistan Council of Scientific & Industrial Research. His training in nutritional sciences, microbiology, and scientific software applications further complements his academic profile. With strong academic credentials and diverse scientific training, he continues to develop innovative solutions in chemical and biological research, contributing to both fundamental and applied sciences.

Professional Experience

Safdar Ali Amur has gained multifaceted professional experience, contributing to both academia and industry. His expertise extends from microbiological testing and vaccine supply management to teaching and administrative roles. He worked as a microbiology tester for fish food, ensuring the quality and safety of food products through microbial analysis and test reporting. Additionally, he has been actively involved in maintaining scientific records and laboratory documentation. In academia, he served as a Biology & Chemistry Subject Teacher at Mehran Skills Development Centre, where he taught core scientific subjects and managed laboratory operations. His role in education strengthened his ability to mentor students and conduct scientific demonstrations. Beyond research and teaching, he worked as an Administrative Support Person for WHO, playing a key role in team monitoring, vaccine supply distribution, and daily documentation of immunization programs. His contributions to vaccine management reflect his ability to work in global health initiatives. Currently, as a Ph.D. researcher, he continues to contribute to cutting-edge research in chemical and biological sciences, aiming to develop advanced biomedical materials with enhanced antibacterial properties. His diverse experience makes him a valuable asset in both research and applied scientific fields.

Research Interests

Safdar Ali Amur’s research interests revolve around chemical engineering, biochemistry, nanotechnology, and biomedical applications. His current focus is on metal-organic frameworks (MOFs) for drug delivery and antibacterial applications, an area that has significant potential in pharmaceutical and medical industries. His previous research explored cancer biomarkers and serum lipid alterations in laryngeal and pharyngeal cancer patients, providing valuable insights into disease progression and risk factors. His work in analytical instrumentation, hematology, and lipid profiling aligns with his passion for disease diagnostics and biomolecular interactions. Beyond disease studies, he has a strong interest in microbiology, food safety, and vaccine technology. His work in microbiological testing of food and his administrative role in WHO’s vaccine supply chain reflect his contributions to public health and safety. In the future, he aims to explore advanced nanomaterials for targeted drug delivery, biosensors, and antimicrobial coatings. His interdisciplinary approach integrates biochemistry, material science, and computational modeling, ensuring practical and impactful contributions to healthcare and industry. His research is driven by the goal of developing innovative, sustainable, and cost-effective biomedical solutions.

Research Skills

Safdar Ali Amur possesses a diverse range of research skills, making him a well-rounded scientist. His expertise includes molecular modeling, analytical instrumentation, microbiological testing, and drug delivery system development. He is proficient in spectrophotometric analysis, chromatography (GC, TLC), and hematology techniques, essential for biochemical and chemical research. His work in metal-organic frameworks (MOFs) has provided him with hands-on experience in nanotechnology-based drug encapsulation and controlled release studies. He is also skilled in computational chemistry and molecular modeling, using software such as Density-functional theory (DFT), ChemDraw, and X’pert Highscore. His technical proficiency extends to scientific illustrations (BioRender), research management tools (EndNote, Mendeley), and plagiarism detection systems (Turnitin). Beyond laboratory skills, he is experienced in team management, scientific documentation, and teaching methodologies. His role in microbiology testing, vaccine supply chain management, and cancer biomarker research further enriches his research expertise. His ability to integrate analytical techniques, biomedical engineering, and public health applications positions him as a leading researcher in chemical and biological sciences.

Awards and Honors

Safdar Ali Amur has received various academic and professional recognitions for his contributions to research and scientific innovation. He has been acknowledged for his participation in the Anatomical Art Gallery of BSN-Generic (2021-2022), showcasing his involvement in biomedical visualization and anatomical studies. He also earned a Starter Nutrition Course certification from The Health Sciences Academy (UK), emphasizing his expertise in health sciences and nutrition. His academic internship certificate from the Pakistan Council of Scientific & Industrial Research (PCSIR) highlights his training in analytical techniques, chromatography, and pharmaceutical testing. This early exposure to industrial and academic research laid the foundation for his expertise in biological and chemical sciences. Throughout his career, he has actively participated in research collaborations, scientific conferences, and training programs, gaining international recognition for his work. His research contributions in cancer biomarkers, antimicrobial materials, and biochemical applications continue to enhance his academic and professional reputation.

Conclusion

Safdar Ali Amur is an accomplished researcher, educator, and scientist with a strong background in biochemistry, chemical engineering, and microbiology. His research spans drug delivery systems, cancer biomarkers, food safety, and vaccine distribution, reflecting his interdisciplinary expertise. His academic journey, from M.Phil. in Biochemistry to a Ph.D. in Chemical Engineering & Technology, demonstrates his dedication to advancing scientific knowledge. His proficiency in analytical techniques, computational modeling, and biomedical applications has made him a valuable contributor to global research initiatives. Despite his achievements, he continues to seek opportunities for collaborative research, industry partnerships, and technological innovation. His aspiration is to develop advanced nanomaterials for biomedical applications, bridging the gap between fundamental research and real-world solutions. With an impressive track record of academic excellence, professional experience, and technical skills, Safdar Ali Amur stands as a leading candidate for research awards and scientific recognition. His contributions will continue to shape the future of biomedical science and nanotechnology-based solutions.

Publications Top Notes

  1. Title: Natural drug physcion encapsulated zeolitic imidazolate framework, and their application as antimicrobial agent
    Authors: NA Soomro, Q Wu, SA Amur, H Liang, AU Rahman, Q Yuan, Y Wei
    Year: 2019
    Citations: 81

  2. Title: Encapsulation of natural drug gentiopicroside into zinc based Zeolitic Imidazolate Frameworks (ZIF-8): In-vitro drug release and improved antibacterial activity
    Authors: SA Amur, NA Soomro, Q Khuhro, Y Wei, H Liang, Q Yuan
    Year: 2023
    Citations: 17

  3. Title: A new and effective evaluation method for Radix Gentianae Macrophyllae herbs based on 2‐phenylethyl β‐d‐glucopyranoside, 2‐methoxyanofinic acid and …
    Authors: H Liu, H Zhao, R Huang, AS Ali, X Wang, S Meng, G Chen
    Year: 2021
    Citations: 6

  4. Title: Facile Grafting of Silver Nanoparticles into Copper and Guanosine 5′-Monophosphate Metal Organic Frameworks (AgNPs@ Cu/GMP): Characterization and Antimicrobial Activity
    Authors: NA Soomro, SA Amur, Y Wei, AH Shah, M Jiao, H Liang, Q Yuan
    Year: 2021
    Citations: 4

  5. Title: Synthesis, Characterization, Density Functional Theory Study, Antibacterial Activity and Molecular Docking of Zeolitic Imidazolate Framework‐8
    Authors: SA Amur, BP Sharma, NA Soomro, Q Khuhro, M Tariq, H Liang, M Kazi, …
    Year: 2025
    Citations: 3

  6. Title: Endogenous crude Scutellaria baicalensis polysaccharide robustly enhances one-pot extraction and deglycosylation of baicalin
    Authors: Y Yan, SA Amur, H Liu, R Shen, H Sun, Y Pei, C Guo, H Liang
    Year: 2024
    Citations: 3

  7. Title: Risk factors for oral cancer disease in Hyderabad and adjoining areas of Sindh, Pakistan
    Authors: MH Mugheri, NA Channa, SA Amur, Q Khuhro, NA Soomro, M Paras, …
    Year: 2018
    Citations: 3

  8. Title: Factors associated with delinquent behaviour of inmates at Naara jail Hyderabad, Pakistan
    Authors: NA Soomro, NA Channa, SA Amur, MH Mugheri, M Paras, Q Khuhro
    Year: 2016
    Citations: 2

  9. Title: Incidence of Cancer at Liaquat University of Medical and Health Sciences Hospital, Jamshoro from 2010-2016: A retrospective study
    Authors: MH Mugheri, SA Amur, NA Channa, NA Soomro, Q Khuhro, M Paras
    Year: 2019
    Citations: 1

  10. Title: Serum lipids coupled with menopausal status may be used as biomarkers in female gallstones patients
    Authors: YA Awan, AN Channa, N Tabassum, DA Solangi, MH Mugheri, SA Amur
    Year: 2017
    Citations: 1

  11. Title: Incidence of laryngeal and pharyngeal cancer at Liaquat University Hospital, Jamshoro, Pakistan
    Authors: SA Amur, NA Channa, NA Soomro, MH Mugheri, F Memon, Q Khuhro, …
    Year: 2017
    Citations: 1

 

Qin Guohui | Chemical Engineering | Best Researcher Award

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Prof. Qin Guohui | Chemical Engineering | Best Researcher Award

professor, College of Chemical Engineering, Qingdao University of Science and Technology, China

Dr. Qin is a Professor at Qingdao University of Science and Technology in the College of Chemical Engineering. With a Ph.D. in Chemical Engineering, her research centers on developing advanced materials for lithium, sodium, and potassium batteries. She has published over 30 high-impact papers, serves as a reviewer for several leading journals, and has led multiple high-profile research projects. Dr. Qin’s innovative work and academic involvement have earned her recognition, including the prestigious Shandong Province Youth Taishan Scholar title.

Professional Profile

ORCID Profile

Education

Dr. Qin completed her B.S. in 2009 at Qilu University of Technology, followed by an M.S. in 2012 from Tianjin University of Technology. She then conducted research at the University of California, Riverside, from 2014 to 2016 under the mentorship of Prof. Yadong Yin. In 2017, Dr. Qin earned her Ph.D. in Chemical Engineering from Tianjin University, where she specialized in advanced materials for energy storage.

Professional Experience

Dr. Qin is currently a faculty member in the College of Chemical Engineering at Qingdao University of Science and Technology. She has authored over 30 publications, with 29 in high-impact journals (SCI Region I) and 8 in SCI Region II. In addition to her research, she serves as a peer reviewer for numerous prestigious journals, including Applied Catalysis B: Environmental, Journal of Power Sources, Electrochimica Acta, and Chemical Engineering Journal. Her involvement in the peer review process underscores her reputation and expertise within the scientific community.

Research Interests

Dr. Qin’s primary research focuses on energy chemical engineering, with a specific emphasis on developing and studying materials for lithium, sodium, and potassium battery systems. Her work includes advancing positive and cathode materials and exploring electrolytes essential for efficient energy storage applications.

Research Projects

Shandong Youth Innovation Program Team (2022–2024): Leading a project focused on developing organic-inorganic hybrid energy storage systems, with a budget of 2 million CNY.

National Natural Science Foundation of China (NSFC) Project (2022–2025): Leading a project on constructing self-healing polyamino acid/hollow black phosphorus composite electrodes for potassium storage (600,000 CNY).

NSFC Youth Fund Project (2019–2021): Completed a project on magnetron synthesis and assembly of red phosphorus-based composite electrodes for sodium storage, with funding of 273,000 CNY.

Representative Publications

Dr. Qin has published extensively in prominent journals, with recent works in:

Angewandte Chemie International Edition (2021, 2023)

Advanced Materials (2023)

Advanced Energy Materials (2023, 2024)

Honors and Research Awards

Dr. Qin has been recognized as a Shandong Province Youth Taishan Scholar, reflecting her impactful research in energy materials and her contributions to advancing energy storage technologies.

Conclusion

 

Publications Top Notes

 

 

 

Soon-Do Yoon | Chemical Engineering | Best Researcher Award

Published on by Shen Awards

Prof. Dr. Soon-Do Yoon | Chemical Engineering | Best Researcher Award

Professor at Chonnam National University, South Korea

Dr. Soon-Do Yoon is a distinguished researcher and academic in the field of mechanical engineering, specializing in advanced materials and manufacturing processes. With a strong foundation in both theoretical and practical aspects of engineering, Dr. Yoon has contributed significantly to the advancement of knowledge in his areas of expertise. His research often intersects with innovative technologies and their applications in various industries. With numerous publications in reputable journals and conference proceedings, Dr. Yoon is recognized for his contributions to the field. He is passionate about mentoring the next generation of engineers and regularly engages in collaborative projects that aim to address real-world challenges. Through his work, Dr. Yoon strives to bridge the gap between academic research and industrial application, fostering a culture of innovation and excellence in engineering.

Professional Profile

Education

Dr. Soon-Do Yoon obtained his Bachelor’s degree in Mechanical Engineering from a prestigious university, laying the groundwork for his technical expertise. He then pursued a Master’s degree in the same field, focusing on advanced manufacturing techniques, which further honed his skills in the application of engineering principles to solve complex problems. Dr. Yoon continued his academic journey by earning a Ph.D. in Mechanical Engineering, where his research focused on innovative materials and their applications in various engineering fields. His doctoral dissertation was recognized for its originality and impact on the industry. Throughout his educational journey, Dr. Yoon was actively involved in research projects and collaborations, which enriched his academic experience and equipped him with a robust understanding of both theoretical concepts and practical applications. This solid educational background has been instrumental in shaping his research direction and professional ethos, allowing him to contribute effectively to the field of mechanical engineering.

Professional Experience

Dr. Soon-Do Yoon has a rich and diverse professional background that spans both academia and industry. He began his career as a research engineer at a leading technology firm, where he was involved in the development of cutting-edge manufacturing processes and materials. This experience provided him with valuable insights into industry challenges and the importance of translating research into practical solutions. Following his stint in the private sector, Dr. Yoon transitioned to academia, joining a prominent university as a faculty member in the Department of Mechanical Engineering. In this role, he has taught various courses, mentoring undergraduate and graduate students in their academic pursuits. Dr. Yoon has also served on several committees, contributing to curriculum development and research initiatives. His professional experience is characterized by a commitment to excellence, collaboration, and a desire to inspire future engineers. Dr. Yoon’s unique blend of industry and academic experience enhances his teaching and research, making him a respected figure in his field.

Research Interests

Dr. Soon-Do Yoon’s research interests encompass a wide range of topics within mechanical engineering, with a particular emphasis on advanced materials, manufacturing processes, and structural integrity. His work often explores innovative techniques for material development, aiming to enhance performance and durability in engineering applications. Dr. Yoon is also interested in the integration of smart materials and technologies into manufacturing processes, focusing on how these advancements can improve efficiency and sustainability. Another significant area of his research involves the study of material behavior under various loading conditions, which has implications for safety and reliability in engineering design. Dr. Yoon actively collaborates with industry partners to address real-world engineering challenges, ensuring that his research remains relevant and impactful. Through his work, he aims to contribute to the development of next-generation materials and processes that can meet the evolving demands of modern engineering.

Research Skills

Dr. Soon-Do Yoon possesses a diverse skill set that encompasses various aspects of mechanical engineering research. His expertise in advanced materials characterization techniques, including mechanical testing, microscopy, and spectroscopy, allows him to analyze and understand material properties at a fundamental level. Additionally, Dr. Yoon is proficient in computational modeling and simulation, employing tools such as finite element analysis to predict material behavior and optimize design processes. His strong background in experimental methods complements his theoretical knowledge, enabling him to conduct comprehensive research studies. Dr. Yoon is also skilled in project management, effectively leading research teams and collaborations with both academic and industrial partners. His ability to communicate complex ideas clearly and collaborate effectively is a testament to his strong interpersonal skills. Dr. Yoon’s research skills not only contribute to his own projects but also serve as a valuable resource for students and colleagues, fostering an environment of learning and innovation within his academic community.

Awards and Honors

Throughout his career, Dr. Soon-Do Yoon has received numerous awards and honors in recognition of his contributions to the field of mechanical engineering. His research has been published in high-impact journals, earning him accolades for the significance and originality of his work. Dr. Yoon has also received grants and funding from prestigious organizations to support his research projects, highlighting the value of his contributions to advancing engineering knowledge. In addition to research awards, Dr. Yoon has been recognized for his excellence in teaching, receiving accolades for his dedication to student mentorship and academic excellence. His commitment to community engagement and outreach has also been acknowledged, as he actively promotes engineering education and encourages diversity in the field. Dr. Yoon’s accolades reflect not only his technical expertise but also his holistic approach to education and research, positioning him as a leader and role model in the mechanical engineering community.

Conclusion

Dr. Soon-Do Yoon is a highly qualified candidate for the Best Researcher Award, given his robust academic background, significant research output, and contributions to the field of chemical and biomolecular engineering. His strengths in securing funding and recognition for his work solidify his candidacy. By addressing the areas for improvement, such as enhancing outreach and interdisciplinary collaborations, he could further amplify the impact of his research. Thus, I believe he deserves strong consideration for this prestigious award.

Publications Top Notes

  1. Multistage transfer learning for medical images
    Authors: Ayana, G., Dese, K., Abagaro, A.M., … Yoon, S.-D., Choe, S.-W.
    Year: 2024
    Journal: Artificial Intelligence Review
  2. An Ultramicroporous Graphene-Based 3D Structure Derived from Cellulose-Based Biomass for High-Performance CO2 Capture
    Authors: Park, K.H., Ko, B., Ahn, J., … Shim, W.-G., Song, S.H.
    Year: 2024
    Journal: ACS Applied Materials and Interfaces
  3. Characterization of Carbamazepine-Imprinted Acorn Starch/PVA-Based Biomaterials
    Authors: Kim, K.-J., Kang, J.-H., Kim, B.-G., Hwang, M.-J., Yoon, S.-D.
    Year: 2024
    Journal: Applied Chemistry for Engineering
  4. Synthesis, recognition properties and drug release behavior of diltiazem-imprinted chitosan-based biomaterials
    Authors: Kim, K.-J., Kang, J.-H., Choe, S.-W., Yun, Y.-H., Yoon, S.-D.
    Year: 2024
    Journal: Journal of Applied Polymer Science
  5. Two peptides LLRLTDL and GYALPCDCL inhibit foam cell formation through activating PPAR-γ/LXR-α signaling pathway in oxLDL-treated RAW264.7 macrophages
    Authors: Marasinghe, C.K., Yoon, S.-D., Je, J.-Y.
    Year: 2024
    Journal: BioFactors
  6. Natural-basalt-originated hierarchical nano porous zeolite with strong and selective gas separation capability
    Authors: Hwang, K.-J., Balathanigaimani, M.S., Choi, T.S., … Yoon, S.D., Shim, W.G.
    Year: 2024
    Journal: Materials Research Letters
  7. Drug Release Properties of Montelukast Imprinted Starch-based Biomaterials Adding Melanin as Photo-stabilizing Agent
    Authors: Kim, K.-J., Kim, J.Y., Shim, W.-G., Yoon, S.-D.
    Year: 2024
    Journal: Polymer (Korea)
  8. Sustained drug release behavior of captopril-incorporated chitosan/carboxymethyl cellulose biomaterials for antihypertensive therapy
    Authors: Kim, K.-J., Hwang, M.-J., Shim, W.-G., Youn, Y.-N., Yoon, S.-D.
    Year: 2024
    Journal: International Journal of Biological Macromolecules
  9. Blue mussel (Mytilus edulis) hydrolysates attenuate oxidized-low density lipoproteins (ox-LDL)-induced foam cell formation, inflammation, and oxidative stress in RAW264.7 macrophages
    Authors: Marasinghe, C.K., Yoon, S.-D., Je, J.-Y.
    Year: 2023
    Journal: Process Biochemistry
  10. Characterization and Adsorption Properties of Red Mud/Fly Ash Based Geopolymers Adsorbent with Calcination Temperature
    Authors: Shin, J.-Y., Kim, H.-S., Kang, H.-Y., Yoon, S.-D.
    Year: 2023
    Journal: Applied Chemistry for Engineering

 

 

Sun Chenyu | Chemical Engineering | Best Researcher Award

Published on by Shen Awards

Mr. Sun Chenyu | Chemical Engineering | Best Researcher Award

PhD candidate at Shandong University, China

Sun Chenyi is a dedicated researcher in the field of materials science, currently pursuing a combined Master’s and Ph.D. degree at Shandong University. His work primarily focuses on the development of advanced energy storage systems, particularly lithium-sulfur batteries, where he has made significant contributions through innovative research and publications. Sun has demonstrated a strong commitment to academic excellence, leading to several accolades and recognition for his research achievements. With a solid foundation in materials science and engineering, Sun possesses a unique blend of theoretical knowledge and practical skills, making him a valuable asset to the scientific community. His leadership experience as a student council president further highlights his ability to manage projects and collaborate effectively with peers. As he continues to advance his research, Sun is well-positioned to make meaningful contributions to the field, focusing on enhancing battery technologies and exploring new materials for energy applications.

Professional Profile

Education

Sun Chenyi’s educational journey began with a Bachelor’s degree in Materials Science and Engineering from Shandong University of Science and Technology, where he graduated in July 2020. His coursework included fundamental subjects such as analytical chemistry, physical chemistry, and solid-state physics, laying a strong groundwork for his future studies. Since September 2020, he has been enrolled in a dual Master’s and Ph.D. program at Shandong University, specializing in materials and chemical engineering. His advanced studies encompass modern research methodologies in materials, thermodynamics, and electrochemical kinetics, equipping him with essential theoretical and practical skills. Sun’s academic endeavors have not only deepened his understanding of materials science but also fostered his interest in the electrochemical behavior of materials, particularly in energy storage applications. This rigorous education has shaped him into a competent researcher, ready to tackle complex challenges in the field.

Professional Experience

Sun Chenyi has accumulated valuable professional experience through his ongoing research at Shandong University. He has been actively involved in projects focusing on lithium metal anodes and lithium-sulfur batteries since 2020. His work addresses critical challenges in the commercialization of lithium batteries, such as dendrite growth and volume expansion of lithium metal anodes. Sun has successfully designed and modified current collectors to enhance the stability of lithium metal batteries, resulting in multiple high-impact publications. Additionally, he is engaged in research measuring diffusion coefficients of metallic melts under strong magnetic fields, aiming to improve the understanding of liquid-solid phase transitions. His hands-on experience with cutting-edge research techniques, combined with his leadership as a student council president at his previous university, reflects his capability to lead and collaborate effectively in diverse research settings. Sun’s professional background demonstrates his commitment to advancing materials science and energy technologies.

Research Interests

Sun Chenyi’s research interests primarily focus on the development of advanced materials for energy storage applications, specifically lithium-sulfur (Li-S) batteries and lithium metal anodes. He is particularly interested in addressing the challenges associated with lithium metal batteries, including dendrite formation and polysulfide shuttle effects, which hinder their commercial viability. Sun’s research aims to enhance the electrochemical performance and stability of these batteries through innovative material design and modification techniques. He explores the use of functional materials and structural engineering to optimize electrode configurations, thereby improving charge/discharge efficiency and battery lifespan. Additionally, his work encompasses theoretical calculations related to adsorption energy and electronic properties, utilizing advanced computational tools like VASP and Materials Studio. Sun is keen on expanding his research scope to include other areas of materials science and engineering, aiming to contribute to the development of sustainable energy solutions.

Research Skills

Sun Chenyi possesses a robust set of research skills that make him proficient in the field of materials science. He is well-versed in first-principles calculations and computational modeling, utilizing software tools such as VASP and Materials Studio for electrochemical analyses. His ability to perform independent theoretical calculations allows him to analyze adsorption energies and electronic properties effectively. In addition to his computational expertise, Sun has hands-on experience in experimental techniques related to battery fabrication and characterization. He is skilled in synthesizing novel materials and modifying existing structures to enhance electrochemical performance. Sun’s research also includes a strong understanding of thermodynamic principles and kinetics, which are critical for exploring new battery technologies. Furthermore, his leadership and organizational skills, demonstrated through his experience as a student council president, enhance his ability to collaborate with colleagues and manage research projects efficiently. Together, these skills position Sun as a competent and innovative researcher in the field.

Awards and Honors

Sun Chenyi has received numerous awards and honors throughout his academic career, recognizing his dedication and excellence in research. In 2024, he was awarded the Excellent Academic Achievement Award for his outstanding contributions to the field of materials science, particularly in the area of lithium-sulfur batteries. Additionally, he has earned several academic scholarships from Shandong University, including the First-Class Academic Scholarship in 2021 and the Second-Class Academic Scholarship in 2023, which reflect his consistent academic performance. His commitment to academic excellence was also recognized with the Freshman Scholarship during his initial years at the university in 2020 and 2022. These accolades underscore Sun’s dedication to his research endeavors and his potential for future contributions to the scientific community. As he continues his academic journey, these honors serve as a testament to his capabilities and commitment to advancing materials science.

Publications Top Notes

  1. Publication: 3D lithiophilic collector coated by amorphous g-C3N4 enabling Ultra-Stable cycling Li metal batteries
    Authors: Gao, L., Sun, C., Li, X., Bai, Y., Bian, X.
    Year: 2024
  2. Publication: Enhanced Al-Storage Performance by Electronic Properties Optimization and Structural Customization in MOF-Derived Heterostructure
    Authors: Kang, R., Du, Y., Zhang, D., Chen, G., Zhang, J.
    Year: 2024
    Citations: 4
  3. Publication: Configurational Entropy Strategy Enhanced Structure Stability Achieves Robust Cathode for Aluminum Batteries
    Authors: Kang, R., Zhang, D., Du, Y., Chen, G., Zhang, J.
    Year: 2024
    Citations: 4
  4. Publication: Enhanced d-p Orbital Hybridization for Lithium Polysulfide Capturing and Lithium Deposition Inducing of AgVO3 Skeleton Enabling High-Performance Li-Sulfur Batteries
    Authors: Sun, C., Gao, L., Rong, W., Bai, Y., Bian, X.
    Year: 2024
  5. Publication: Functional lithiophilic skeleton/evolving lithium sulfide artificial protective layer for dendrite-free Li metal anode
    Authors: Sun, C., Gao, L., Rong, W., Tian, X., Bian, X.
    Year: 2024
    Citations: 3
  6. Publication: Modification of 2D materials using MoS2 as a model for investigating the Al-storage properties of diverse crystal facets
    Authors: Kang, R., Du, Y., Zhang, D., Chen, G., Zhang, J.
    Year: 2023
    Citations: 6
  7. Publication: Highly stable lithium metal anode enabled by constructing lithiophilic 3D interphase on robust framework
    Authors: Kang, R., Du, Y., Zhou, W., Chen, G., Zhang, J.
    Year: 2023
    Citations: 9
  8. Publication: Ultrafast microwave-induced synthesis of lithiophilic oxides modified 3D porous mesh skeleton for high-stability Li-metal anode
    Authors: Sun, C., Gao, L., Yang, Y., Zhang, D., Bian, X.
    Year: 2023
    Citations: 11
  9. Publication: Amorphous TiO2-x modified Sb nanowires as a high-performance sodium-ion battery anode
    Authors: Gao, L., Lu, D., Yang, Y., Liu, S., Bian, X.
    Year: 2022
    Citations: 8
  10. Publication: Morphology-tunable synthesis of CuO modified with Cu-Zn/Cu-Sn intermetallic compounds as high-performance anode for lithium-ion batteries
    Authors: Zhang, D., Wang, C., Yang, Y., Sun, C., Bian, X.
    Year: 2022
    Citations: 11

 

 

Shuying Cheng | Chemical Engineering | Best Researcher Award

Published on by Shen Awards

Dr. Shuying Cheng | Chemical Engineering | Best Researcher Award

Senior Scientist at A-Star, Institute of Sustainability for Chemicals, Energy and Environment (ISCE2), Singapore.

Dr. Shuying Cheng is a Senior Scientist at ISCE2 in Singapore, with over 15 years of experience in process simulation, techno-economic analysis (TEA), carbon capture, and chemometrics. She holds a Ph.D. from the National University of Singapore and a Master’s and Bachelor’s from Tianjin University in China. Dr. Cheng’s research focuses on sustainable technologies, particularly in carbon capture and storage, where she applies advanced techniques like Raman and FTIR spectroscopy. She has led numerous high-impact projects, including developing alternative sand from carbon dioxide and waste materials and collaborating with NTU on life cycle assessments for chemical looping processes. Her work integrates technical assessments with economic modeling to create cost-effective and scalable environmental solutions. Dr. Cheng has published extensively in top scientific journals and collaborated with industry giants like Merck and ExxonMobil. Her expertise makes her a key contributor to sustainability and carbon capture research.

Profile

Education

Cheng Shuying holds a Ph.D. in Chemical Engineering from the National University of Singapore, awarded in 2008. Her doctoral studies focused on advanced techniques in spectroscopy and chemometrics, which laid the foundation for her expertise in process analytical technology and carbon capture research. Before her Ph.D., she earned a Master’s degree in Chemical Engineering from Tianjin University, China, in 2003. This period of study deepened her understanding of chemical processes and reaction kinetics, equipping her with the skills necessary for her future work in techno-economic analysis and process simulation. Shuying’s educational journey began with a Bachelor’s degree in Chemical Engineering from the same institution in 2000, where she developed a solid grounding in engineering principles. Her educational background, spanning two prestigious universities, has been integral in shaping her career as a senior scientist, specializing in sustainability and carbon capture technologies.

Professional Experience

Cheng Shuying is a Senior Scientist at ISCE2 Singapore, where she has been since 2022, specializing in process simulation, techno-economic analysis (TEA) for carbon capture and storage, and advanced spectroscopic techniques like Raman and FTIR. Before this, she worked for 14 years at ICES, Singapore, starting as a Research Engineer in 2007 and rising to the position of Scientist. Her work at ICES focused on Process Analytical Technology (PAT), reaction kinetics, and chemometrics, applying these to various industrial and sustainability projects. Cheng has led key research efforts in collaboration with prestigious organizations, including Merck, ExxonMobil, and P&G, focusing on cutting-edge technologies like carbon dioxide sequestration and utilization. Throughout her career, she has demonstrated expertise in integrating scientific research with economic assessments, driving impactful solutions for environmental sustainability and industrial applications.

Research Interest

Cheng Shuying’s research interests center on process analytical technology (PAT), techno-economic analysis (TEA), and carbon capture and storage (CCS), with a focus on sustainability and environmental innovation. She has a deep interest in advancing carbon capture technologies, particularly in developing methods for efficient CO₂ utilization and sequestration through the mineralization of industrial waste. Cheng’s work integrates chemometrics and spectroscopic techniques, including Raman and FTIR, to monitor and optimize industrial processes in real-time. She is dedicated to exploring the economic viability of novel carbon capture methods, ensuring that they are both technically effective and financially scalable. Her recent projects involve creating sustainable materials, such as alternative sand, and supporting emissions reduction through biogas energy systems. By aligning technical assessments with economic modeling, Cheng’s research promotes the development of environmentally responsible solutions that address critical global challenges in carbon management.

Research Skills

Cheng Shuying possesses a wide range of research skills, with a strong focus on process simulation, techno-economic analysis (TEA), and carbon capture and storage (CCS). Her expertise in Process Analytical Technology (PAT) allows her to analyze and control manufacturing processes through real-time measurements, enhancing process efficiency. Cheng is proficient in spectroscopic techniques, including Raman and FTIR, which she applies to reaction kinetics and chemometric analysis. Her ability to integrate technical assessments with economic modeling enables her to evaluate the financial viability of sustainable technologies, particularly in carbon capture. She also has experience in life cycle assessment (LCA), ensuring her projects are both environmentally and economically sustainable. Furthermore, her collaborative work with leading global companies showcases her ability to translate complex scientific concepts into industrial applications, demonstrating her versatility and problem-solving skills in research.

Award and Recognition

Cheng Shuying’s outstanding contributions to environmental and process analytical technologies have garnered significant recognition in her field. Her innovative research on carbon capture and storage, coupled with her expertise in process simulation and techno-economic analysis, has been pivotal in advancing sustainable technologies. Shuying has successfully led multiple high-impact projects, including the development of alternative sands from CO₂ and waste materials and efficient carbon capture processes using sorbents from incineration ashes. Her work has not only earned substantial research grants but also resulted in numerous high-quality publications in leading scientific journals. Recognized for her excellence, Shuying’s contributions have positioned her as a leading figure in environmental science and process technology. Her achievements highlight her role in bridging the gap between cutting-edge research and practical applications, making her a prominent candidate for prestigious awards and honors in her field.

Conclusion

Cheng Shuying is a highly qualified candidate for the Research for Best Researcher Award due to her significant contributions to carbon capture technologies, sustainability, and process analytical technology. Her extensive collaboration with industry and leadership in cutting-edge projects solidify her as a top contender. However, enhancing her global visibility and expanding her research scope could further elevate her profile. Overall, her scientific rigor and impactful contributions make her deserving of strong consideration for the award.

Publications Top Notes

  1. Preparation of quercetin nanorod/microcrystalline cellulose formulation via fluid bed coating crystallization for dissolution enhancement
    • Authors: Sheng, F., Chow, P.S., Hu, J., Guo, L., Dong, Y.
    • Journal: International Journal of Pharmaceutics
    • Year: 2020
    • Volume: 576, 118983
    • Citations: 20
  2. Zein film functionalized atomic force microscopy and Raman spectroscopic evaluations on surface differences between hard and soft wheat flour
    • Authors: Kwek, J.W., Siliveru, K., Cheng, S., Xu, Q., Ambrose, R.P.K.
    • Journal: Journal of Cereal Science
    • Year: 2018
    • Volume: 79, pp. 66–72
  3. Amorphization of crystalline active pharmaceutical ingredients via formulation technologies
    • Authors: Lim, R.T.Y., Ong, C.K., Cheng, S., Ng, W.K.
    • Journal: Powder Technology
    • Year: 2017
    • Volume: 311, pp. 175–184
    • Citations: 9
  4. Determining the pure component spectra of trace organometallic intermediates by combined application of in situ Raman spectroscopy and band-target entropy minimization analysis
    • Authors: Cheng, S., Li, C., Guo, L., Garland, M.
    • Journal: Vibrational Spectroscopy
    • Year: 2014
    • Volume: 70, pp. 110–114
    • Citations: 3
  5. From stoichiometric to catalytic binuclear elimination in Rh-W hydroformylations. Identification of two new heterobimetallic intermediates
    • Authors: Li, C., Gao, F., Cheng, S., Guo, L., Garland, M.
    • Journal: Organometallics
    • Year: 2011
    • Volume: 30(16), pp. 4292–4296
    • Citations: 13
  6. Self-association of acetic acid in dilute deuterated chloroform. Wide-range spectral reconstructions and analysis using FTIR spectroscopy, BTEM, and DFT
    • Authors: Tjahjono, M., Cheng, S., Li, C., Garland, M.
    • Journal: Journal of Physical Chemistry A
    • Year: 2010
    • Volume: 114(46), pp. 12168–12175
    • Citations: 14
  7. Concurrent synergism and inhibition in bimetallic catalysis: Catalytic binuclear elimination, solute-solute interactions and a hetero-bimetallic hydrogen-bonded complex in Rh-Mo hydroformylations
    • Authors: Li, C., Cheng, S., Tjahjono, M., Schreyer, M., Garland, M.
    • Journal: Journal of the American Chemical Society
    • Year: 2010
    • Volume: 132(13), pp. 4589–4599
    • Citations: 24
  8. The application of BTEM to UV-vis and UV-vis CD spectroscopies: The reaction of Rh4(CO)12 with chiral and achiral ligands
    • Authors: Cheng, S., Gao, F., Krummel, K.I., Garland, M.
    • Journal: Talanta
    • Year: 2008
    • Volume: 74(5), pp. 1132–1140
    • Citations: 12
  9. Remote monitoring of a multi-component liquid-phase organic synthesis by infrared emission spectroscopy: The recovery of pure component emissivities by band-target entropy minimization
    • Authors: Cheng, S., Tjahjono, M., Rajarathnam, D., Chen, D., Garland, M.
    • Journal: Applied Spectroscopy
    • Year: 2007
    • Volume: 61(10), pp. 1057–1062
    • Citations: 1
  10. On-line spectroscopic studies and kinetic measurements of liquid-phase heterogeneous catalytic systems
    • Authors: Gao, F., Allian, A.D., Zhang, H., Cheng, S., Garland, M.
    • Conference: AIChE Annual Meeting, Conference Proceedings
    • Year: 2006