Nursaya Makayeva | Carbon Capture and Storage | Best Researcher Award

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Dr. Nursaya Makayeva | Carbon Capture and Storage | Best Researcher Award

Senior Researcher | Institute of Combustion Problems | Kazakhstan

Nursaya Makayeva is a dynamic educator and analytical chemist from Al-Farabi Kazakh National University, specializing in research and development, quality control, and advanced analytical methods. With several years of experience in academic and research settings, she has contributed significantly to the fields of catalysis, methane decomposition, and sustainable energy solutions. Her expertise bridges both teaching and applied research, making her a valuable contributor to the scientific community.

Professional Profile

ORCID

Education

Nursaya Makayeva pursued her higher education at Al-Farabi Kazakh National University, where she completed her bachelor’s and master’s degrees in chemistry. She continued her academic journey by enrolling in a doctoral program, deepening her expertise in catalysis and advanced chemical processes. Alongside her formal academic qualifications, she gained practical research experience through internships at the Center of Physico-Chemical Methods of Research and Analysis of Al-Farabi KazNU and at the Republican Center for Structural Research in Tbilisi, Georgia. These opportunities enriched her academic foundation by combining theoretical learning with hands-on laboratory practice.

Experience

Her professional career combines teaching, research, and practical application. As an educator, she designed engaging curricula and provided academic support that fostered student growth. In research, she served as a junior researcher at institutions such as the Institute of Combustion Problems and the Center of Physico-Chemical Methods of Research and Analysis, focusing on experimental design, catalytic systems, and advanced laboratory analysis. Skilled in techniques like chromatography, voltammetry, and TPR-H2, she applied these methods to produce reliable scientific outcomes. Her collaborations with senior researchers, contributions to R&D projects, and participation in international conferences further highlight her growing role in the global scientific community.

Research Focus

Nursaya’s primary research interests lie in catalysis, hydrogen production, and carbon utilization, with a particular emphasis on methane decomposition processes. Her studies explore the development and optimization of catalysts, including mono- and bimetallic systems, for efficient energy conversion. She has also investigated the effects of preparation methods and the incorporation of rare earth oxides, such as cerium, on catalyst performance. Her recent contributions extend to sustainable solutions in carbon dioxide utilization, where she has co-authored review studies on catalytic, photocatalytic, and electrocatalytic processes for CO₂ conversion. By addressing the intersection of renewable energy, environmental protection, and advanced materials, her research supports global efforts toward cleaner energy systems and reduced greenhouse gas emissions.

Publication Top Notes

Title: Advancements in catalytic, photocatalytic, and electrocatalytic CO₂ conversion processes: Current trends and future outlook
Year: 2024

Title: Effects of cerium oxide on the activity of Fe-Ni/Al₂O₃ catalyst in the decomposition of methane
Year: 2024

Title: Electrochemical synthesis of Fe-containing composite for decomposition of methane into COx-free hydrogen and nano-carbon
Year: 2022

Title: Effect of Preparation Method on the Activity of Fe₂O₃-NiO/γ-Al₂O₃ Catalyst in Decomposition of Methane
Year: 2022

Conclusion

Nursaya Makayeva exemplifies the qualities of an emerging leader in chemistry, combining strong academic foundations with impactful research and practical applications. Her dedication to advancing catalytic science, her ability to merge teaching with high-quality research, and her collaborative approach to scientific problem-solving highlight her as a deserving candidate for recognition. Through her contributions to methane decomposition, hydrogen production, and carbon dioxide utilization, she has positioned herself at the forefront of sustainable energy research. Her growing body of publications, active participation in international collaborations, and innovative patent demonstrate her potential to continue shaping the field of chemistry with lasting impact.

Yao Lu | Thermoelectrics | Best Researcher Award

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Prof. Yao Lu | Thermoelectrics | Best Researcher Award

Assistant Professor, Southern University of Science and Technology, China

Dr. Yao Lu is an accomplished scientist and Associate Professor at the School of Microelectronics, Southern University of Science and Technology (SUSTech), China. With a strong academic background and a research portfolio that spans advanced thermoelectric materials, GaN-based LED technology, and micro-thermoelectrics for on-chip thermal management, Dr. Lu has become a leading voice in the field of sustainable electronics and energy materials. His work blends academic rigor with technological innovation, resulting in impactful contributions to scientific knowledge, patented inventions, and real-world applications.

💠Professional Profile

ORCID

🏆 Strengths for the Award

Strong Academic and Research Background
Dr. Lu possesses a Ph.D. in Materials Science and Engineering from Tongji University and has steadily built his expertise through progressive academic and industry roles, including R&D, postdoctoral research, and tenure-track professorship.

Pioneering Research Contributions
His research in flexible thermoelectrics and micro-thermoelectric materials has led to multiple high-impact innovations. Notable is his 2023 publication in Nature Nanotechnology, one of the highest-ranking journals in the field, reflecting groundbreaking work on Bi₂Te₃ films. His work is widely cited, with individual papers garnering citations exceeding 165, signifying significant academic impact.

Independent Funding Success
Dr. Lu has secured multiple prestigious grants, including from:

China National Postdoctoral Program for Innovative Talents

National Natural Science Foundation of China (NSFC)

GuangDong Basic Research Foundation
These showcase his capability as a principal investigator and his recognition within national scientific funding systems.

Publication Quality and Volume
Dr. Lu has authored over 17 SCI-indexed publications, with many in top-tier journals like Nature Nanotechnology, Energy & Environmental Science, Materials Today Physics, and ACS Applied Materials & Interfaces. Several of these are ESI Highly Cited and “Hot Papers,” highlighting both relevance and timeliness.

🎓 Education

Dr. Lu began his academic journey with a Bachelor of Science degree in Optical Science and Technology from the University of Jinan in 2010. He continued at the same institution to obtain his Master of Science in Optics in 2012, where he deepened his understanding of photonic and optoelectronic systems. Eager to explore more advanced materials, he pursued a Ph.D. in Materials Science and Engineering at Tongji University, which he completed in December 2019. His doctoral research laid the foundation for his pioneering work in flexible thermoelectric materials, integrating the principles of optics, semiconductors, and nanotechnology.

💼 Experience

Dr. Lu’s professional journey began in industry, where he served as an R&D Engineer and later Supervisor at Inspur Group Co., Ltd. from 2012 to 2016. This early experience in a technology-driven industrial setting enriched his technical competencies and shaped his practical approach to research. Transitioning to academia, he joined Southern University of Science and Technology as a Postdoctoral Researcher in 2020. During this period, he contributed significantly to national research initiatives and rapidly distinguished himself as an emerging leader. In recognition of his potential, he was appointed Guest Professor at Songshan Lake Materials Laboratory in 2022. In 2024, Dr. Lu commenced his tenure-track position as Assistant Professor at SUSTech, where he continues to mentor students and lead cutting-edge research.

🔬 Research Focus

Dr. Lu’s research is centered on the development of advanced functional materials with a focus on flexible thermoelectrics, GaN-based light-emitting diodes, and micro-thermoelectrics for on-chip thermal management. His innovative work addresses the growing need for energy-efficient, miniaturized, and flexible electronics. By engineering high-performance thermoelectric films and composite structures, he is enabling new possibilities in wearable devices and next-generation electronics. His interdisciplinary research spans materials synthesis, device fabrication, and performance optimization, reflecting a deep understanding of both fundamental science and applied technology. His findings have laid the groundwork for more effective energy harvesting and thermal regulation systems, making his work critical to future advancements in microelectronics and sustainable technologies.

🏆 Awards and Honors

Throughout his career, Dr. Lu has been recognized for his outstanding contributions to science and innovation. In 2023, he was honored with the Dongguan Characteristic Talents Class II designation, recognizing his leadership in the field. He was named an Outstanding Postdoctoral Fellow by Southern University of Science and Technology in 2020. Earlier, he won the Excellent Report Award at the Chinese Materials Conference in 2019 and received First Prize in the 6th Shanghai College Students New Material Innovation and Creativity Competition the same year. His early promise was evident when he was named Outstanding Student of Shandong Province in 2012. These accolades are a testament to his sustained academic excellence, innovation, and dedication.

📚 Publications Top Notes

Modulating Carrier Transport by Cross-Dimensional Compositing of Ag₂Se/MXene for High-Performance Flexible Thermoelectrics

Journal: Journal of Materials Chemistry A (2024)
DOI: 10.1039/D4TA02249A
Contributors: Jie Qin, Yao Lu, Wenjing Liu, Zhangli Du, Xiang Li, Tianpeng Ding, Jianghe Feng, Yong Du, Qinfei Ke, Xin Wang

Summary:
This study presents a novel cross-dimensional compositing strategy integrating one-dimensional Ag₂Se nanowires with two-dimensional MXene nanosheets to form highly efficient flexible thermoelectric films. The synergistic interaction between the Ag₂Se and MXene phases significantly enhances electrical conductivity and optimizes carrier scattering, leading to improved thermoelectric performance. This work demonstrates a promising route for designing next-generation wearable energy devices with superior flexibility and thermal-to-electrical conversion capabilities. 💎

Probing Temperature‐Dependence of Hydrogen Bonding in Condensed Polymeric Materials with Aggregation‐Induced Emission

Journal: ChemistrySelect (Scheduled: August 12, 2024)
DOI: 10.1002/slct.202402045
Contributors: Yao Lu, Xinyue Fan, Shijie Ge

Summary:
In this innovative research, the team utilized aggregation-induced emission (AIE) fluorescence probes to investigate hydrogen bonding behavior in polymeric materials under varying temperatures. By linking AIE-active molecules to specific functional groups within polymers, the authors successfully visualized changes in hydrogen bonding dynamics with high sensitivity. This technique provides valuable insights into the fundamental interactions within soft materials and opens new avenues for designing smart responsive polymers in sensors and actuators. 🧪

Staggered-Layer-Boosted Flexible Bi₂Te₃ Films with High Thermoelectric Performance

Journal: Nature Nanotechnology (2023)
DOI: 10.1038/S41565-023-01457-5
Contributors: Yao Lu, Yi Zhou, Wu Wang, Mingyuan Hu, Xiege Huang, Dasha Mao, Shan Huang, Lin Xie, Peijian Lin, Binbin Jiang, Bo Zhu, Jianghe Feng, Jinxin Shi, Qing Lou, Yating Huang, Jianmin Yang, Junhua Li, Guodong Li, Jingqi He

Summary:
This groundbreaking work introduces staggered-layer engineering to enhance the thermoelectric performance of flexible Bi₂Te₃ films. By manipulating the nanoscale layering, the researchers achieved simultaneous improvement in electrical conductivity and reduced thermal conductivity, resulting in a record-breaking ZT value for flexible films. This achievement marks a significant leap toward the commercialization of high-efficiency, flexible thermoelectric materials for energy harvesting and wearable electronics. The publication in Nature Nanotechnology highlights its transformative impact on the field.

Exceptional Power Factor of Flexible Ag/Ag₂Se Thermoelectric Composite Films

Journal: Chemical Engineering Journal (2022)
DOI: 10.1016/J.CEJ.2022.134739
Contributors: Xiang Li, Yao Lu, Kefeng Cai, Mingyuan Gao, Yating Li, Zixing Wang, Miaomiao Wu, Ping Wei, Wenyu Zhao, Yong Du, Shuang Shen

Summary:
This article reports on the development of Ag/Ag₂Se flexible thermoelectric composite films that exhibit a remarkable power factor, surpassing previously reported values in similar materials. The incorporation of nanoscale silver provided conductive pathways while maintaining mechanical flexibility, making these composites ideal for wearable thermoelectric applications. The study offers vital insights into the optimization of metal–semiconductor interfaces and demonstrates practical application potential in low-power electronic devices. 💎

Exceptionally High Power Factor Ag₂Se/Se/Polypyrrole Composite Films for Flexible Thermoelectric Generators

Journal: Advanced Functional Materials (2022)
DOI: 10.1002/ADFM.202106902
Contributors: Yating Li, Qing Lou, Jianmin Yang, Kefeng Cai, Ying Liu, Yiming Lu, Yang Qiu, Yao Lu, Zixing Wang, Miaomiao Wu, Yong Du, etc.

Summary:
This high-impact research article presents a unique ternary composite system combining Ag₂Se, elemental Se, and polypyrrole to achieve an ultra-high power factor for flexible thermoelectric films. The hierarchical structure allows for optimized carrier mobility, phonon scattering, and mechanical integrity, significantly improving energy conversion efficiency. This work has implications for the development of lightweight, flexible thermoelectric generators suitable for wearable and autonomous electronic devices. Published in Advanced Functional Materials, the research reflects the cutting-edge innovation of Dr. Lu and collaborators.

🏁 Conclusion

Dr. Yao Lu stands at the forefront of innovation in energy materials and microelectronics. His distinguished academic training, multidisciplinary research, impactful publications, patented inventions, and active scientific engagement make him a highly deserving candidate for a prestigious research award. His work not only advances the scientific community but also contributes directly to the development of sustainable and intelligent technologies for the future. Through dedication, creativity, and leadership, Dr. Lu continues to inspire the next generation of researchers and drive progress in the global scientific landscape.