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

 

Kafi Mohamed Hamed | Chemical Engineering | Best Researcher Award

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Mr. Kafi Mohamed Hamed | Chemical Engineering | Best Researcher Award

University lecturer from Bule Hora University, Ethiopia

Kafi Mohamed Hamed is a dedicated academic and researcher based in Bule Hora, Ethiopia, currently serving as an instructor in the Department of Chemical Engineering at Bule Hora University. With over five years of professional experience in higher education, he has been actively engaged in teaching, supervising undergraduate student projects, conducting research, and providing community service. His commitment to academic excellence is reflected in his efforts to bridge theoretical knowledge with practical application, particularly in areas such as process engineering, nanotechnology, and environmental protection. Kafi has a strong foundation in chemical engineering, having earned both his BSc and MSc in the discipline with commendable academic records. His technical proficiency spans a wide range of simulation and analytical software, which he employs in research and teaching activities. In addition to his teaching responsibilities, Kafi is involved in awareness programs and community engagement initiatives aimed at addressing local engineering challenges. His active participation in professional associations, such as the Ethiopian Society of Chemical Engineering, further illustrates his commitment to professional development and contribution to the field. Despite the need for further research publications and international exposure, Kafi is steadily building a profile as a promising researcher with potential to make significant contributions in his field.

Professional Profile

Education

Kafi Mohamed Hamed has pursued a robust academic path in the field of chemical engineering. He began his higher education journey at Adigrat University in Ethiopia, where he earned his Bachelor of Science (BSc) in Chemical Engineering. Graduating with a CGPA of 3.60/4, he developed a strong foundation in core chemical engineering principles, including thermodynamics, process control, transport phenomena, and unit operations. Following his undergraduate studies, Kafi enrolled in the MSc program in Process Engineering at Jimma University’s Institute of Technology. He completed his postgraduate studies with a CGPA of 3.64/4, focusing on advanced process design, optimization, and chemical process simulations. His graduate education allowed him to gain deeper insights into industrial processes, environmental considerations, and research methodologies in chemical engineering. To enhance his teaching and pedagogical skills, he also completed formal pedagogical training and a Higher Diploma Programme (HDP) at Bule Hora University. These additional qualifications prepared him for an academic career by improving his instructional techniques and understanding of curriculum development. His educational background not only reflects academic rigor but also his continuous pursuit of excellence in teaching and applied research within chemical engineering.

Professional Experience

Kafi Mohamed Hamed has over five years of professional experience in academia, having joined Bule Hora University on September 27, 2018. Since his appointment, he has held the position of Instructor in the Department of Chemical Engineering under the College of Engineering and Technology. His responsibilities include delivering core and elective courses across the undergraduate chemical engineering curriculum, supervising final-year student research projects, and actively participating in both institutional research and community service programs. His involvement extends beyond the classroom, as he has also taken on administrative and leadership roles, such as serving as department head by delegation and participating in departmental committees. These roles have helped him develop strong managerial and organizational skills. Kafi is deeply engaged in bridging education and community development, evident from his participation in community service teams that work on raising awareness and providing technical solutions to local industrial and environmental problems. His work experience also includes mentoring students, curriculum design, and contributing to the operational effectiveness of the department. He is a member of the Ethiopian Society of Chemical Engineering and has participated in an industrial internship at Gulelle Soap and Detergent Factory, providing him exposure to real-world applications of chemical engineering processes.

Research Interest

Kafi Mohamed Hamed has cultivated a wide-ranging set of research interests that span both traditional and emerging areas in chemical engineering. His primary areas of interest include composite materials, nanotechnology, polymer science, and process optimization. He is particularly drawn to solving engineering problems that intersect with environmental and energy concerns, such as wastewater treatment and sustainable energy engineering. These research interests reflect a clear alignment with global scientific priorities aimed at environmental protection and sustainability. Kafi’s multidisciplinary approach allows him to explore innovative materials and processes that can improve the efficiency and environmental impact of industrial operations. His interest in process optimization is evident in his use of simulation tools and modeling software to enhance chemical processes and resource utilization. Additionally, his focus on nanotechnology and polymer science opens opportunities for developing advanced functional materials with applications in various sectors, including energy storage, environmental remediation, and biomedical engineering. Through his teaching and final-year project supervision, he continuously integrates these research themes into student-led investigations. Kafi’s interest in community-relevant research also aligns his academic work with local developmental goals, further underscoring his commitment to both scientific advancement and societal benefit.

Research Skills

Kafi Mohamed Hamed possesses a diverse and practical set of research skills that support his academic and investigative work in chemical engineering. His technical expertise spans a range of analytical, simulation, and process design tools essential for research and teaching. He is proficient in MATLAB and Simulink for system modeling and analysis, as well as Aspen HYSYS and Aspen Plus for chemical process simulation and design. His familiarity with ANSYS and CFD software indicates capability in computational fluid dynamics and mechanical modeling. In the area of data analysis and experimental design, Kafi utilizes tools such as Design Expert, Origin Pro, and Chemdraw. His proficiency in process integration software like HINT reflects an understanding of energy efficiency and pinch analysis techniques. He also employs visualization and documentation tools like Edraw Max and Photoshop to enhance research communication. Kafi demonstrates an ability to bridge theoretical concepts with practical experimentation and simulation, a skill particularly important in process and environmental engineering. Furthermore, his background includes hands-on experience in industrial settings during his internship, and his supervision of undergraduate projects shows his skill in guiding research methodology. These competencies equip him to tackle multidisciplinary challenges and pursue advanced research in material and process innovation.

Awards and Honors

Although Kafi Mohamed Hamed’s CV does not list specific individual awards or honors, his academic and professional journey includes several noteworthy achievements and recognitions. He graduated with distinction at both undergraduate and postgraduate levels, securing CGPAs of 3.60 and 3.64 respectively. His admission into a competitive MSc program in Process Engineering at Jimma University and his successful completion of the program reflect academic merit and dedication. Kafi has also been entrusted with significant institutional responsibilities, such as serving as department head by delegation and contributing to curriculum development and quality assurance activities. These appointments suggest recognition by his peers and institutional leadership for his competence, reliability, and leadership potential. Additionally, his participation in Ethiopia’s national professional body, the Ethiopian Society of Chemical Engineering (ESCHE), illustrates his commitment to professional growth and recognition within the engineering community. His selection for internship training at Gulelle Soap and Detergent Factory demonstrates early professional promise and exposure to applied chemical engineering practices. While he may not yet have received high-profile research awards, Kafi’s consistent academic performance, institutional trust, and active involvement in community and professional activities serve as significant indicators of his potential for future honors and research accolades.

Conclusion

Kafi Mohamed Hamed is a promising early-career academic with a strong foundation in chemical engineering and a commitment to research, teaching, and community service. His educational qualifications, combined with over five years of experience at Bule Hora University, have positioned him as a capable instructor and an emerging researcher. His areas of research interest—ranging from composite materials and nanotechnology to wastewater treatment and energy engineering—demonstrate an alignment with contemporary global challenges and sustainable development goals. He possesses a broad range of research skills, particularly in simulation, modeling, and process design, which are valuable for conducting meaningful and applied research. However, to enhance his competitiveness for prestigious awards like the Best Researcher Award, he would benefit from increasing his scholarly output through peer-reviewed publications, conference participation, and research collaborations. Moreover, gaining international exposure and securing research funding will further elevate his academic profile. Despite these areas for improvement, Kafi has already laid a solid foundation for a successful research career. His dedication to both academic excellence and community service underscores his potential to become a key contributor to the advancement of chemical engineering in Ethiopia and beyond.

Publications Top Notes

  1. Title: Optimizing of Nanocellulose Extraction From Highland Bamboo Arundinaria alpina for Sustainable Bio‐Nanomaterials via Response Surface Methodology
    Journal: Advances in Polymer Technology
    Type: Journal article
    Publication Date: January 2025

Saeid Maghami | Chemical Engineering | Best Researcher Award

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Dr. Saeid Maghami | Chemical Engineering | Best Researcher Award

Assistant Professor at Yazd University, Iran

Dr. Saeid Maghami is an accomplished researcher and educator specializing in chemical and polymer engineering. Currently serving as a faculty member at Yazd University, Iran, he has built an impressive career in both academia and industry. Dr. Maghami’s research focuses on innovative areas such as membrane gas separation, polymeric and mixed matrix membranes, and water treatment. With a robust educational background, international research exposure, patents, and numerous high-impact publications, he has contributed significantly to advancing his field. His career reflects a commitment to combining theoretical research with practical applications, addressing industrial and societal challenges through engineering innovation.

Professional Profile

Education

Dr. Maghami holds a PhD in Chemical Engineering from Isfahan University of Technology, Iran (2013-2019), where he focused on modeling operational temperature and pressure effects on gas separation properties of membranes. He earned his MSc in Chemical Engineering from Shiraz University, Iran (2010-2012), where he explored CO2 removal via microalgae. His undergraduate studies in chemical engineering at Sahand University of Technology, Iran (2006-2010), laid the foundation for his research, focusing on environmental pollutants. His educational journey reflects a strong emphasis on tackling real-world engineering problems through innovative approaches.

Professional Experience

Dr. Maghami has a diverse professional background encompassing both academia and industry. He currently serves as a faculty member in the Department of Chemical and Polymer Engineering at Yazd University. He previously worked as an engineering manager at Shirin Salamat Partikan Company, focusing on industrial-scale isomalt production from sucrose. His teaching experience spans over a decade, during which he has taught courses like Process Control, Heat Transfer, and Industrial Chemistry. Additionally, his eight-month research visit to the University of Zaragoza, Spain, highlights his commitment to global academic collaboration and advanced research.

Research Interests

Dr. Maghami’s research interests lie in cutting-edge areas of chemical and polymer engineering. He focuses on membrane gas separation, modeling the performance of polymeric and mixed matrix membranes, and characterizing interfacial regions in polymer-particle composites. His work also includes water treatment processes and the production and purification of sugar alcohols, reflecting a balance between theoretical exploration and industrial application. Dr. Maghami’s interdisciplinary approach addresses critical challenges in sustainability and innovation.

Research Skills

Dr. Maghami possesses advanced skills in research methodologies and engineering tools. His expertise includes mathematical modeling, membrane performance optimization, and interfacial morphology characterization. He is proficient in using software like MATLAB, HYSIS, and ASPEN for process simulation and data analysis. These skills, combined with his deep understanding of polymer science and engineering principles, enable him to conduct impactful research and develop practical solutions to complex problems.

Awards and Honors

Dr. Maghami’s contributions to chemical and polymer engineering have been recognized through various awards and honors. Notably, he holds a patent on characterizing polymer-particle interfaces in composite materials. His research papers have been published in top-tier journals, and he has actively participated in international conferences. These achievements underscore his innovation and dedication to advancing his field.

Conclusion

Dr. Saeid Maghami is a distinguished researcher whose career epitomizes the integration of academic excellence, industrial innovation, and practical application. His extensive research contributions, combined with his teaching and leadership roles, demonstrate his commitment to advancing chemical and polymer engineering. With a strong foundation in education, exceptional research skills, and global collaborations, Dr. Maghami is well-positioned to make continued significant contributions to his field.

Publication Top Notes

  1. A comprehensive modeling approach for determining the role and nature of interfacial morphology in mixed matrix membranes
    Authors: Zarabadipoor, M., Maghami, S., Mehrabani-Zeinabad, A., Sadeghi, M.
    Year: 2021
    Journal: Computational Materials Science
    Citations: 5
  2. Influence of solvent, Lewis acid–base complex, and nanoparticles on the morphology and gas separation properties of polysulfone membranes
    Authors: Maghami, S., Sadeghi, M., Baghersad, S., Zornoza, B.
    Year: 2021
    Journal: Polymer Engineering and Science
    Citations: 6
  3. Gas separation through polyurethane–ZnO mixed matrix membranes and mathematical modeling of the interfacial morphology
    Authors: Fakhar, A., Maghami, S., Sameti, E., Shekari, M., Sadeghi, M.
    Year: 2020
    Journal: SPE Polymers
    Citations: 11
  4. Determination of maximum possible contribution of porous particles in gas transport properties of their corresponding mixed matrix membranes
    Authors: Maghami, S., Sadeghi, M., Mehrabani-Zeinabad, A., Simiari, M.
    Year: 2020
    Journal: SPE Polymers
    Citations: 3
  5. Influence of solvent and nanoparticles on the morphology and gas separation properties of copolyimide membranes
    Authors: Maghami, S., Sadeghi, M., Khoshkam, M., Chenar, M.P.
    Year: 2020
    Journal: Journal of Applied Polymer Science
    Citations: 6
  6. Characterization of the polymer/particle interphase in composite materials by molecular probing
    Authors: Maghami, S., Shahrooz, M., Mehrabani-Zeinabad, A., Zornoza, B., Sadeghi, M.
    Year: 2020
    Journal: Polymer
    Citations: 21
  7. Mathematical modeling of temperature and pressure effects on permeability, diffusivity and solubility in polymeric and mixed matrix membranes
    Authors: Maghami, S., Mehrabani-Zeinabad, A., Sadeghi, M., Téllez, C., Coronas, J.
    Year: 2019
    Journal: Chemical Engineering Science
    Citations: 34
  8. Influence of blend composition and silica nanoparticles on the morphology and gas separation performance of PU/PVA blend membranes
    Authors: Shirvani, H., Maghami, S., Isfahani, A.P., Sadeghi, M.
    Year: 2019
    Journal: Membranes
    Citations: 19
  9. The Role of Interfacial Morphology in the Gas Transport Behavior of Nanocomposite Membranes: A Mathematical Modeling Approach
    Authors: Maghami, S., Sadeghi, M., Mehrabani-Zeinabad, A., Zarabadi, M., Ghalei, B.
    Year: 2019
    Journal: Industrial and Engineering Chemistry Research
    Citations: 14
  10. Recognition of polymer-particle interfacial morphology in mixed matrix membranes through ideal permeation predictive models
    Authors: Maghami, S., Sadeghi, M., Mehrabani-Zeinabad, A.
    Year: 2017
    Journal: Polymer Testing
    Citations: 16

 

Zhiyu Mao | Chemical Engineering | Best Researcher Award

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Assoc. Prof. Dr. Zhiyu Mao | Chemical Engineering | Best Researcher Award

Associate Professor at Dalian Institute of Chemical Physics, China

Dr. Zhiyu Mao is an accomplished researcher and associate professor at the Dalian Institute of Chemical Physics, Chinese Academy of Sciences. With a Ph.D. in Chemical Engineering from the University of Waterloo, his research spans multiple areas within electrochemical energy storage systems, battery management, and advanced material design. Over the past 9+ years, Dr. Mao has gained substantial expertise in the development, testing, and mathematical modeling of energy storage systems, specifically lithium-ion batteries, fuel cells, and supercapacitors. His work focuses on understanding failure mechanisms in batteries, the aging process, and the implementation of artificial intelligence for battery management systems (BMS). Along with his academic career, Dr. Mao has worked in industry, collaborating with companies such as CWZE Power Inc. and Tianjin Lishen Battery Co., where he led R&D efforts on battery safety, performance evaluation, and system integration. His research has resulted in over 30 published papers and 13 patents. Dr. Mao has proven himself as a leader in the electrochemical energy field and continues to make significant strides in advancing energy storage technologies.

Professional Profile

Education:

Dr. Zhiyu Mao’s academic journey is marked by a strong foundation in chemical and materials engineering. He completed his Ph.D. in Chemical Engineering at the University of Waterloo, Canada, in 2016, where he specialized in battery materials, electrochemical systems, and modeling techniques for energy storage devices. Before this, Dr. Mao obtained his M.Sc. in Chemical Engineering from Taiyuan University of Technology, China, where he focused on electrode reaction kinetics for lithium-ion batteries. His undergraduate studies were completed at Inner Mongolia University, China, where he earned a B.Sc. in Materials Chemistry. Throughout his educational career, Dr. Mao honed his skills in both experimental research and theoretical modeling, laying the groundwork for his later contributions to the field of electrochemical energy storage. His research during his Ph.D. involved the development of innovative methodologies for understanding the behavior of battery materials, which he later applied to various real-world applications, including electric vehicles (EVs) and renewable energy storage systems. His diverse educational background has equipped him with a broad set of skills in both theoretical and applied chemistry, making him a leader in electrochemical engineering.

Professional Experience:

Dr. Zhiyu Mao has built an impressive career spanning both academia and industry, contributing significantly to the fields of electrochemical engineering and energy storage systems. Currently, Dr. Mao holds the position of Associate Professor at the Dalian Institute of Chemical Physics, Chinese Academy of Sciences, where he leads research on electrochemical energy storage, battery modeling, and fault warning systems for batteries. Prior to this, he served as a professor at Zhejiang Normal University, focusing on the dynamics of embedded materials and failure mechanisms in energy storage systems. In addition to his academic roles, Dr. Mao has accumulated significant industrial experience. He worked as a research scientist at CWZE Power Inc., where he led the R&D of advanced long-life lead-carbon batteries. He also contributed to the development of high-performance Li-ion cells at Newtech Power Inc., playing a key role in battery design, pilot plant testing, and performance evaluation. His industrial roles have provided him with valuable hands-on experience in the commercialization of electrochemical systems, allowing him to bridge the gap between research and practical application. This combination of academic and industrial expertise has made Dr. Mao a well-rounded and influential figure in his field.

Research Interests:

Dr. Zhiyu Mao’s research interests lie at the intersection of electrochemical engineering, advanced materials, and energy storage systems. His primary focus is on the design and optimization of electrochemical energy storage devices, particularly lithium-ion batteries, sodium-ion batteries, fuel cells, and hybrid supercapacitors. Dr. Mao is particularly interested in understanding the microscopic dynamics of embedded materials and the mechanisms that lead to battery degradation and failure. This includes exploring issues like solid-electrolyte interphase (SEI) growth, transition metal dissolution, and lithium plating. He also works on the development of artificial intelligence (AI) and big data analytics for battery management systems (BMS), aiming to improve state-of-charge estimation, fault prediction, and battery life-cycle management. Dr. Mao’s research spans both theoretical and experimental work, using advanced electrochemical and non-electrochemical techniques to characterize battery performance and failure modes. He is also engaged in developing advanced materials for batteries, including silicon and graphite-based electrodes, to improve energy density, rate capability, and cycle life. His research on smart energy grids and energy storage systems for renewable energy applications is pushing the boundaries of energy storage technology and its integration into broader energy systems.

Research Skills:

Dr. Zhiyu Mao possesses a wide range of research skills that are central to his work in electrochemical energy storage systems. His technical expertise includes experimental techniques like cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), galvanostatic intermittent titration (GITT), and constant current/constant voltage (CC/CV) cycling, as well as non-electrochemical characterization methods such as scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy (EDX), X-ray diffraction (XRD), and differential scanning calorimetry (DSC). Dr. Mao is highly skilled in mathematical modeling and simulation of electrochemical systems, particularly in the development of physics-based models for battery aging and life prediction. He has expertise in applying advanced AI techniques and big data analysis to energy storage and management systems, particularly in the optimization of battery performance and fault detection. Dr. Mao is also proficient in the design and fabrication of battery systems, including the selection and optimization of materials, cell assembly, and testing. His interdisciplinary approach, combining fundamental electrochemical principles with applied engineering, has allowed him to make significant contributions to both academic research and industry.

Awards and Honors:

Dr. Zhiyu Mao’s outstanding contributions to electrochemical research and energy storage systems have earned him several accolades throughout his career. While specific awards are not detailed in his CV, his impressive body of work, including over 30 publications in prestigious journals such as the Journal of the Electrochemical Society and Electrochimica Acta, demonstrates the recognition he has received in the academic community. Furthermore, Dr. Mao’s patents, totaling 13 internationally, highlight the innovative nature of his work, particularly in battery materials, energy storage systems, and management technologies. His collaborative work with industry leaders, such as Newtech Power Inc. and CWZE Power Inc., also underscores his ability to apply his research to real-world problems, advancing both scientific understanding and practical applications. His research on advanced materials, battery aging, and AI for battery management has established him as a thought leader in the field of electrochemical energy storage. Although specific honors and awards are not listed, his scientific output, patent portfolio, and industry collaborations place him in a strong position for recognition.

Conclusion:

Dr. Zhiyu Mao is a highly accomplished researcher and academic with a proven track record in advancing the field of electrochemical energy storage systems. His extensive research, spanning from battery design to artificial intelligence applications for battery management, has positioned him as a leader in the field. Dr. Mao’s interdisciplinary expertise, coupled with his industrial experience, makes him uniquely qualified to bridge the gap between academic research and practical, real-world applications in energy storage and renewable energy technologies. His contributions, including over 30 published papers and 13 patents, highlight his innovative approach and impact on the industry. While there is room for further engagement in sustainability efforts and public outreach, Dr. Mao’s work continues to push the boundaries of what is possible in energy storage systems. His dedication to both research and mentorship, along with his commitment to technological advancement, makes him a strong candidate for recognition and accolades in the scientific community. Dr. Mao’s future contributions will undoubtedly continue to shape the next generation of energy storage technologies, furthering the global transition toward sustainable energy solutions.

Publication Top Notes

  1. Title: Significant Enhancement of Electrocatalytic Activity of Nickel-Based Amorphous Zeolite Imidazolate Frameworks for Water Splitting at Elevating Temperatures
    Authors: Iqbal, M.F., Xu, T., Li, M., Xu, P., Chen, Z.
    Year: 2024
    Citations: 1
  2. Title: Optimizing Annealing Treatment of Mesoporous MoO₂ Nanoparticles for Enhancement of Hydrogen Evolution Reaction
    Authors: Iqbal, M.F., Xu, T., Li, M., Zhang, J., Chen, Z.
    Year: 2024
    Citations: 1
  3. Title: A Hybrid Deep Learning Approach for Remaining Useful Life Prediction of Lithium-Ion Batteries Based on Discharging Fragments
    Authors: Liu, Y., Hou, B., Ahmed, M., Feng, J., Chen, Z.
    Year: 2024
    Citations: 8
  4. Title: A Review on Iron-Nitride (Fe₂N) Based Nanostructures for Electrochemical Energy Storage Applications: Research Progress, and Future Perspectives
    Authors: Sajjad, M., Zhang, J., Mao, Z., Chen, Z.
    Year: 2024
    Citations: 10
  5. Title: Long-Life Lead-Carbon Batteries for Stationary Energy Storage Applications
    Authors: Sajjad, M., Zhang, J., Zhang, S., Mao, Z., Chen, Z.
    Year: 2024
    Citations: 9
  6. Title: A Comprehensive Review of the Pseudo-Two-Dimensional (P2D) Model: Model Development, Solutions Methods, and Applications
    Authors: Hussain, A., Mao, Z., Li, M., Zhang, J., Chen, Z.
    Year: 2024
  7. Title: An Unsupervised Domain Adaptation Framework for Cross-Conditions State of Charge Estimation of Lithium-Ion Batteries
    Authors: Liu, Y., Ahmed, M., Feng, J., Mao, Z., Chen, Z.
    Year: 2024
  8. Title: Design of Lithium Exchanged Zeolite-Based Multifunctional Electrode Additive for Ultra-High Loading Electrode Toward High Energy Density Lithium Metal Battery
    Authors: Gao, Y., Yang, Y., Yang, T., Luo, D., Chen, Z.
    Year: 2024
  9. Title: Deep Learning Powered Lifetime Prediction for Lithium-Ion Batteries Based on Small Amounts of Charging Cycles
    Authors: Liu, Y., Ahmed, M., Feng, J., Mao, Z., Chen, Z.
    Year: 2024
  10. Title: Heat Transfer Analysis of MHD Prandtl-Eyring Fluid Flow with Christov-Cattaneo Heat Flux Model
    Authors: Hussain, A., Mao, Z.
    Year: 2024
    Citations: 10

 

Sun Chenyu | Chemical Engineering | Best Researcher Award

Posted 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

Posted 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