Oh Seok Kwon | Chemical Engineering | Best Researcher Award

Prof. Oh Seok Kwon | Chemical Engineering | Best Researcher Award

Associate Professor at Sungkyunkwan University, South Korea

Dr. Oh Seok Kwon is an accomplished researcher and Associate Professor at the SKKU Advanced Institute of Nanotechnology and Department of Nano Engineering, SungKyunKwan University, South Korea. Born on April 13, 1979, Dr. Kwon has made significant contributions to the fields of nanotechnology, biosensors, and chemical engineering. With an impressive academic background and a career marked by prestigious positions, including postdoctoral roles at Yale University and MIT, Dr. Kwon has focused his research on graphene-based materials and their applications in flexible sensors, bioengineering, and environmental monitoring. His work has garnered wide recognition, reflected in over 5,000 citations and numerous high-impact publications in top-tier journals. Dr. Kwon also serves as a guest editor for Sensors and Polymers and holds a leadership role in advancing nanotechnology research globally. He is committed to advancing scientific knowledge while contributing to technological innovations with practical applications in health, environmental, and industrial sectors.

Professional Profile

Education:

Dr. Oh Seok Kwon earned his Doctor of Philosophy (Ph.D.) in Chemical and Biological Engineering from Seoul National University in 2013, where he conducted groundbreaking research on graphene materials and their applications in flexible sensors. Prior to his Ph.D., he obtained a Master of Science in Chemical Engineering from the same institution in 2010, where he focused on biosensor applications using polypyrrole nanotubes. His academic journey began with a Bachelor of Science in Chemistry from Yeungnam University in South Korea in 2007. His educational path is marked by strong mentorship, including guidance from renowned professors like Jyongsik Jang and Prof. Jaehong Kim. Dr. Kwon’s extensive academic experience laid the foundation for his subsequent research, making him an expert in the synthesis of advanced materials and the development of next-generation sensors.

Professional Experience:

Dr. Oh Seok Kwon currently serves as an Associate Professor at the SKKU Advanced Institute of Nanotechnology and the Department of Nano Engineering at SungKyunKwan University. Before joining SKKU, Dr. Kwon was an Associate Professor at the University of Science and Technology (UST), South Korea, where he contributed significantly to research on nanomaterials and biosensors. He has also worked as a Senior Researcher at the Infectious Research Center at the Korea Research Institute of Bioscience and Biotechnology. In his earlier career, Dr. Kwon held postdoctoral research positions at prestigious institutions such as Yale University and the Massachusetts Institute of Technology, where he advanced his expertise in environmental engineering and material science. His leadership roles in various academic and research initiatives highlight his influence in the field of nanotechnology and his commitment to advancing scientific research.

Research Interests:

Dr. Oh Seok Kwon’s research interests are primarily focused on nanotechnology, graphene materials, and biosensor development. He has pioneered the use of chemical vapor deposition (CVD) to create graphene and its integration into flexible sensor technologies, contributing to advancements in wearable electronics and environmental monitoring. His research also delves into biosensors, specifically those employing polypyrrole nanotubes and graphene for chemical and biological detection. Additionally, Dr. Kwon is exploring the applications of nanomaterials in tissue regeneration, drug delivery, and drug evaluation through 3D bioprinting technologies. He is particularly interested in ultra-sensitive detection methods using energy transfer strategies between nanomaterials, such as graphene and gold nanorods, to improve the performance of sensors. His interdisciplinary work bridges chemistry, biology, and nanotechnology to develop practical solutions for health, environmental, and industrial challenges.

Research Skills:

Dr. Kwon possesses extensive expertise in material science, particularly in the fabrication and application of nanomaterials such as graphene and polypyrrole nanotubes. He is highly skilled in chemical vapor deposition (CVD), a technique critical for growing high-quality graphene. Additionally, Dr. Kwon’s proficiency in sensor design and fabrication is evident in his work on flexible and ultra-sensitive biosensors for environmental and medical applications. His skills extend to the integration of nanomaterials in bioengineering, including tissue regeneration and drug delivery systems. Dr. Kwon is also proficient in various analytical techniques, including scanning electron microscopy (SEM), transmission electron microscopy (TEM), and spectroscopy methods. His multidisciplinary skills in nanomaterials, sensor technology, and bioengineering enable him to lead cutting-edge research projects across diverse scientific fields.

Awards and Honors:

Dr. Oh Seok Kwon’s exceptional research contributions have earned him numerous accolades. He has been widely recognized for his pioneering work in nanotechnology and sensor development. His research publications have received substantial citation recognition, and his h-index of 42 demonstrates the long-lasting impact of his scholarly work. Additionally, Dr. Kwon has served in prestigious roles such as Guest Editor for special issues of MDPI journals Sensors and Polymers, indicating his leadership within the academic community. Although specific awards and honors are not explicitly listed, his role in top-tier research institutes and the editorial board of high-impact journals showcases his standing as a respected figure in the scientific community. His ongoing work continues to shape the future of biosensors and nanotechnology, positioning him for further honors.

Conclusion:

Dr. Oh Seok Kwon is a distinguished researcher with a strong academic background and a proven track record in nanotechnology, biosensors, and chemical engineering. His impressive body of work, particularly in the development of graphene-based materials for flexible sensors, has made significant contributions to various scientific disciplines. With an outstanding citation record and leadership roles in prominent scientific journals, Dr. Kwon is highly regarded in his field. His research has practical implications in health, environmental, and industrial applications, underscoring the societal impact of his work. Dr. Kwon’s multidisciplinary expertise and ongoing commitment to scientific innovation place him among the leading researchers in his field. His career continues to inspire advancements in nanotechnology and biosensor technologies, contributing to global scientific progress.

Publication Top Notes

  • Ultrasensitive flexible graphene-based field-effect transistor (FET)-type bioelectronic nose
    • Authors: SJ Park, OS Kwon, SH Lee, HS Song, TH Park, J Jang
    • Year: 2012
    • Citations: 386
  • Flexible FET-type VEGF aptasensor based on nitrogen-doped graphene converted from conducting polymer
    • Authors: OS Kwon, SJ Park, JY Hong, AR Han, JS Lee, JS Lee, JH Oh, J Jang
    • Year: 2012
    • Citations: 291
  • Polypyrrole nanotubes conjugated with human olfactory receptors: high-performance transducers for FET-type bioelectronic noses
    • Authors: H Yoon, SH Lee, OS Kwon, HS Song, EH Oh, TH Park, J Jang
    • Year: 2009
    • Citations: 257
  • Fabrication of ultrafine metal-oxide-decorated carbon nanofibers for DMMP sensor application
    • Authors: JS Lee, OS Kwon, SJ Park, EY Park, SA You, H Yoon, J Jang
    • Year: 2011
    • Citations: 242
  • Multidimensional conducting polymer nanotubes for ultrasensitive chemical nerve agent sensing
    • Authors: OS Kwon, SJ Park, JS Lee, E Park, T Kim, HW Park, SA You, H Yoon, …
    • Year: 2012
    • Citations: 235
  • High-performance flexible graphene aptasensor for mercury detection in mussels
    • Authors: JH An, SJ Park, OS Kwon, J Bae, J Jang
    • Year: 2013
    • Citations: 229
  • Conducting nanomaterial sensor using natural receptors
    • Authors: OS Kwon, HS Song, TH Park, J Jang
    • Year: 2018
    • Citations: 201
  • Dual-Color Emissive Upconversion Nanocapsules for Differential Cancer Bioimaging In Vivo
    • Authors: OS Kwon, HS Song, J Conde, H Kim, N Artzi, JH Kim
    • Year: 2016
    • Citations: 199
  • Harnessing low energy photons (635 nm) for the production of H2O2 using upconversion nanohybrid photocatalysts
    • Authors: H Kim, OS Kwon, S Kim, W Choi, JH Kim
    • Year: 2016
    • Citations: 188
  • A high-performance VEGF aptamer functionalized polypyrrole nanotube biosensor
    • Authors: OS Kwon, SJ Park, J Jang
    • Year: 2010
    • Citations: 166

 

Shuying Cheng | Chemical Engineering | Best Researcher Award

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