Qinghe Yao | Data-Driven Model | Best Researcher Award

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Prof. Qinghe Yao | Data-Driven Model | Best Researcher Award

Dean at Sun Yat-sen University, Chinađź“–

Dr. Qinghe Yao is a Professor at the School of Aeronautics and Astronautics, Sun Yat-sen University, specializing in large-scale parallel computational fluid dynamics (CFD) and its engineering applications. His research focuses on multi-physics analysis, CFD solver development, and optimization methods for energy systems, including fuel cells and Tokamak plasma simulations. He has led multiple high-impact research projects and has received prestigious awards for his contributions to supercomputing applications.

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Education Background🎓

Dr. Qinghe Yao earned his Ph.D. in [Field] from [University Name], where he specialized in large-scale computational fluid dynamics (CFD) and numerical simulations. He completed his master’s degree in [Field] from [University Name], focusing on multi-physics modeling and optimization techniques. His academic journey began with a bachelor’s degree in [Field] from [University Name], where he developed a strong foundation in fluid mechanics, thermodynamics, and numerical methods. His interdisciplinary education has equipped him with expertise in CFD solver development, high-performance computing, and energy system simulations.

Professional Experience🌱

Dr. Yao is currently a professor at Sun Yat-sen University and has been actively involved in research supported by the National Nature Science Foundation of China and other key scientific programs. His expertise spans large-scale CFD simulations, numerical modeling, and multi-objective optimization for energy systems. He has collaborated on international R&D projects and contributed significantly to computational mechanics and thermal-fluid analysis.

Research Interests🔬

Research interests include:

  • Large-scale parallel CFD algorithm development
  • Multi-physics and multi-objective optimization in energy systems
  • Computational modeling of fuel cells, Tokamak plasma, and heat transfer
  • Lattice Boltzmann methods and immersed boundary techniques

Author Metrics

  • Publications: Multiple papers in high-impact journals such as Journal of Computational Physics, Journal of Fluid Mechanics, and International Journal of Hydrogen Energy
  • Citations: [X] citations (as per ResearchGate/Google Scholar)
  • H-Index: [X]
Awards and Honors
  • Excellent Application Award of Tianhe-II Supercomputer (2016)
  • “Tianhe Star” Excellent Application Award of Tianhe-II Supercomputer (2018)
  • Recognized as a Backbone Teacher by the Ministry of Education (2024)
Publications Top Notes đź“„

1. Studies on the Spray Dried Lactose as Carrier for Dry Powder Inhalation

  • Authors: L. Wu, X. Miao, Z. Shan, Y. Huang, L. Li, X. Pan, Q. Yao, G. Li, C. Wu
  • Journal: Asian Journal of Pharmaceutical Sciences
  • Volume: 9 (6), Pages: 336-341
  • Year: 2015
  • Citations: 115
  • Summary: This study explores the potential of spray-dried lactose as a carrier for dry powder inhalation, enhancing drug delivery efficiency.

2. Multi-Objective Genetic Optimization of the Thermoelectric System for Thermal Management of Proton Exchange Membrane Fuel Cells

  • Authors: T.H. Kwan, X. Wu, Q. Yao
  • Journal: Applied Energy
  • Volume: 217, Pages: 314-327
  • Year: 2018
  • Citations: 67
  • Summary: This research utilizes genetic optimization techniques to improve the thermal management of proton exchange membrane fuel cells (PEMFCs), increasing efficiency and operational stability.

3. Comprehensive Review of Integrating Fuel Cells to Other Energy Systems for Enhanced Performance and Enabling Polygeneration

  • Authors: T.H. Kwan, F. Katsushi, Y. Shen, S. Yin, Y. Zhang, K. Kase, Q. Yao
  • Journal: Renewable and Sustainable Energy Reviews
  • Volume: 128, Article: 109897
  • Year: 2020
  • Citations: 52
  • Summary: A detailed review of the integration of fuel cells with other energy systems to enhance performance, improve efficiency, and enable polygeneration.

4. Liquid Vortexes and Flows Induced by Femtosecond Laser Ablation in Liquid Governing Formation of Circular and Crisscross LIPSS

  • Authors: D. Zhang, X. Li, Y. Fu, Q. Yao, Z. Li, K. Sugioka
  • Journal: Opto-Electronic Advances
  • Volume: 5 (2), Pages: 210066-1-210066-12
  • Year: 2022
  • Citations: 43
  • Summary: This study investigates how femtosecond laser ablation in liquid induces vortex formation, leading to laser-induced periodic surface structures (LIPSS) with circular and crisscross patterns.

5. Exergetic and Temperature Analysis of a Fuel Cell-Thermoelectric Device Hybrid System for Combined Heat and Power Applications

  • Authors: T.H. Kwan, Q. Yao
  • Journal: Energy Conversion and Management
  • Volume: 173, Pages: 1-14
  • Year: [Year]
  • Citations: 41
  • Summary: This paper presents an exergetic and thermal analysis of a hybrid system combining fuel cells and thermoelectric devices for efficient combined heat and power (CHP) applications.

Conclusion

Prof. Qinghe Yao is a highly deserving candidate for the Best Researcher Award, given his outstanding contributions to computational fluid dynamics, energy optimization, and supercomputing applications. His work has significantly advanced aerospace engineering, thermoelectric systems, and CFD methodologies, making a lasting impact on both academia and industry. By further strengthening international collaborations, interdisciplinary approaches, and technology commercialization, his influence in the field can be expanded even further.

This nomination is strongly recommended based on his exceptional research impact, leadership, and scientific innovation.

Lechen Li | Data Science | Best Researcher Award

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Assist. Prof. Dr. Lechen Li | Data Science | Best Researcher Award

Assistant Professor, at Hohai University, Chinađź“–

Lechen Li, Ph.D., is a multidisciplinary researcher and engineer specializing in Engineering Mechanics and Data Science. With a strong foundation in computational mechanics and deep learning, he has contributed significantly to smart grid development, structural health monitoring, and intelligent systems. His award-winning work has been presented at leading international conferences and has garnered recognition for its impact on sustainable infrastructure and advanced engineering solutions.

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Education Background🎓

Dr. Lechen Li is an accomplished scholar in Engineering Mechanics and Data Science with extensive academic and research experience. He earned his Ph.D. in Engineering Mechanics from Columbia University in 2023, achieving an impressive GPA of 3.889/4.0. His doctoral research spanned smart grid development, computational structural dynamics, and data-driven system control. Prior to this, he completed a Master of Science in Data Science at Columbia University in 2019, where he excelled academically with a GPA of 3.917/4.0 and received the prestigious Robert A.W. and Christine S. Carleton Scholarship. Dr. Li’s academic journey began at Sichuan University, China, where he earned his Bachelor’s degree in Engineering Mechanics in 2018. Notably, he secured first prizes in the Zhou Peiyuan National Mechanics Modeling Contest and the First Prize Scholarship twice.

Professional Experience🌱

Dr. Li brings a wealth of industry experience that complements his academic achievements. At Colombo International Container Terminals (CICT) in Sri Lanka, he served as a Data Research Analyst, where he developed machine learning models to optimize port logistics and transportation planning using a dynamic reinforcement learning framework. Earlier, during his tenure as a CAE Analyst at the National Institute of Water, Energy and Transportation in China, Dr. Li conducted advanced simulations using the Extended Finite Element Method (XFEM), providing valuable insights into lateral pile-soil pressure distribution on pile groups.

Research Interests🔬

Dr. Li’s research is centered on:

  • Structural Health Monitoring and Control: Developing advanced deep-learning frameworks for real-time system identification and damage detection.
  • Data-Driven Dynamics: Applying machine learning and signal processing techniques for smart grid optimization and time-series forecasting.
  • Computational Mechanics: Leveraging finite element analysis and XFEM for solving complex engineering problems.
  • Sustainability and Infrastructure: Innovating intelligent systems for energy-efficient monitoring and optimization.

Author Metrics 

  • Publications: Dr. Li has co-authored numerous papers in high-impact journals and conferences, including presenting at the 8th World Conference on Structural Control and Monitoring, where he received the Best Conference Paper Award.
  • Citations: His publications have been widely cited, reflecting the practical and theoretical contributions of his research.
  • Academic Awards: Best Paper Award (8WCSCM, 2022), First Prize in Zhou Peiyuan National Mechanics Modeling Contest (2017).

Publications Top Notes đź“„

1. Short-term apartment-level load forecasting using a modified neural network with selected auto-regressive features

  • Authors: L. Li, C.J. Meinrenken, V. Modi, P.J. Culligan
  • Published in: Applied Energy, 2021
  • Citations: 82
  • Summary: This study focuses on improving short-term electricity load forecasting at the apartment level. The authors developed a modified neural network model that integrates auto-regressive features to enhance prediction accuracy. The approach has implications for optimizing energy management and grid operations in residential buildings.

2.Impacts of COVID-19 related stay-at-home restrictions on residential electricity use and implications for future grid stability

  • Authors: L. Li, C.J. Meinrenken, V. Modi, P.J. Culligan
  • Published in: Energy and Buildings, 2021
  • Citations: 32
  • Summary: This paper examines the effects of COVID-19 lockdowns on residential electricity consumption patterns. The study provides insights into shifts in energy usage due to work-from-home trends and discusses the implications for grid stability and planning.

3.Structural damage assessment through a new generalized autoencoder with features in the quefrency domain

  • Authors: L. Li, M. Morgantini, R. Betti
  • Published in: Mechanical Systems and Signal Processing, 2023
  • Citations: 28
  • Summary: The research introduces a novel autoencoder model that utilizes features in the quefrency domain for structural damage detection. The methodology enhances damage assessment accuracy and offers a new perspective in signal processing for civil infrastructure health monitoring.

4. A machine learning-based data augmentation strategy for structural damage classification in civil infrastructure systems

  • Authors: L. Li, R. Betti
  • Published in: Journal of Civil Structural Health Monitoring, 2023
  • Citations: 8
  • Summary: This work proposes a machine learning-driven data augmentation technique aimed at improving structural damage classification in civil infrastructure systems. The study addresses the challenges of limited data availability in real-world scenarios and improves model robustness.

5. Experimental investigation of the dynamic mechanical properties of concrete under different strain rates and cyclic loading

  • Authors: L. Gan, Y. Liu, Z. Zhang, Z. Shen, L. Li, H. Zhang, H. Jin, W. Xu
  • Published in: Case Studies in Construction Materials, 2024
  • Citations: 4
  • Summary: This experimental study explores the dynamic mechanical behavior of concrete under varying strain rates and cyclic loading conditions. The findings contribute to understanding the material’s performance in diverse loading scenarios, which is crucial for construction and structural design.

Conclusion

Dr. Lechen Li is undoubtedly a highly deserving candidate for the Best Researcher Award. His innovative contributions to engineering mechanics, data science, and structural health monitoring, combined with his solid academic background, make him a strong contender. His research not only pushes the boundaries of technology but also has significant real-world implications for energy management, infrastructure sustainability, and smart grid optimization.

While there are areas where he can expand his influence—such as increasing collaborations with industry, diversifying research, and engaging more broadly with the public—his current achievements already demonstrate his potential for continued leadership in these fields. His work is set to contribute substantially to the next generation of intelligent systems, and with continued focus on bridging academia and industry, Dr. Li will undoubtedly remain at the forefront of his field.

Hence, Dr. Lechen Li’s selection for the Best Researcher Award is both well-earned and a recognition of his future promise as a trailblazer in engineering and data science.