Xiaoci Liang | Thin-film Transistor | Best Researcher Award

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Dr. Xiaoci Liang | Thin-film Transistor | Best Researcher Award

Postdoctor, Sun Yat-sen University, China

Dr. Xiaoci Liang is a postdoctoral researcher at Sun Yat-sen University, specializing in microelectronics and solid-state electronics. After completing his Ph.D., M.E., and B.E. in Microelectronics at the same institution, he has contributed significantly to the study of oxide thin-film transistors and electrolyte-gated transistors. His research is aimed at advancing neuromorphic computing and resistive random-access memory (RRAM) technologies. Dr. Liang’s expertise lies in the development of energy-efficient and high-performance devices for the future of computing and memory systems. His academic achievements include multiple high-impact publications in leading journals like Nature Electronics, The Journal of Physical Chemistry Letters, and Applied Physics Letters, showcasing his innovative work in the field of transistors and memory systems. Dr. Liang continues to push the boundaries of semiconductor research with a focus on sustainability, scalability, and performance optimization.

Profile

Education

Dr. Xiaoci Liang pursued his education at Sun Yat-sen University, where he completed his Bachelor’s degree in Microelectronics (2016), followed by his Master’s in Microelectronics and Solid-State Electronics (2019), and his Ph.D. in the same field (2023). His academic journey has been marked by consistent excellence in the field of microelectronics, culminating in cutting-edge research on oxide thin-film transistors and electrolyte-gated transistors. The focus of his studies has been on integrating advanced materials and device architectures to improve the performance of transistors for next-generation computing and memory technologies. His doctoral research has made a significant impact on the development of neuromorphic computing systems and resistive random-access memory (RRAM), establishing him as a leading researcher in the field. Through his educational path, Dr. Liang has acquired a comprehensive understanding of semiconductor physics and the challenges and opportunities in modern electronics and computing technologies.

Experience

Dr. Xiaoci Liang is currently a postdoctoral researcher at the School of Electronics and Information Technology at Sun Yat-sen University. Since joining the university in 2023, he has focused on developing electrolyte-gated transistors and exploring their potential in neuromorphic computing. His prior research experiences include investigating oxide thin-film transistors and their applications in resistive random-access memory (RRAM). His work on high-performance thin-film transistor technologies has been supported by the Natural Science Foundation of China, and the China National Postdoctoral Program for Innovative Talents. Dr. Liang has published extensively in leading journals such as Nature Electronics, The Journal of Physical Chemistry Letters, and Applied Physics Letters. He has also contributed to high-impact research on energy-efficient devices for neuromorphic systems. His experience has established him as a rising star in the field, with a track record of successful projects and cutting-edge technological advancements.

Research Focus

Dr. Xiaoci Liang’s research primarily revolves around thin-film transistors and electrolyte-gated transistors, with a focus on their application in neuromorphic computing and resistive random-access memory (RRAM). He has explored the underlying physical mechanisms that govern the behavior of high-mobility oxide semiconductors, aiming to enhance their performance for next-generation electronic devices. One of his key research interests is developing low-power, high-speed electrolyte-gated transistors that can emulate biological synapses for neuromorphic computing systems. This research holds the potential to revolutionize artificial intelligence hardware. His projects also focus on improving the scalability and energy efficiency of RRAM devices, which are critical for future memory storage solutions. Through innovative research on material properties and device architecture, Dr. Liang is advancing the integration of these technologies into practical applications. His work is positioning him at the forefront of microelectronics research with a vision for sustainable and high-performance electronics.

Publication Top Notes

  1. Multimode transistors and neural networks based on ion-dynamic capacitance 🌐🧠 Nature Electronics, 2022
  2. Evidence for Pseudocapacitance and Faradaic Charge Transfer in High-Mobility Thin-Film Transistors 🧪🔬 The Journal of Physical Chemistry Letters, 2020
  3. Artificial synaptic transistor with solution-processed InOx channel and AlOx solid electrolyte gate 🧠🔋 Applied Physics Letters, 2020
  4. Efficient Defect Engineering for Solution Combustion Processed In-Zn-O thin films for high performance transistors ⚡🔧 Semiconductor Science and Technology, 2017
  5. Extraction method of trap densities for indium zinc oxide thin-film transistors processed by solution method 🔍⚙️ Thin Solid Films, 2018

 

 

 

 

Bowen Wang | MEMS Accelerometer | Best Researcher Award

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Dr Bowen Wang | MEMS Accelerometer | Best Researcher Award

PhD student, Aerospace Information Research Institute, Chinese Academy of Sciences, China

Bowen Wang is a dedicated Ph.D. candidate at the State Key Laboratory of Transducer Technology, Aerospace Information Research Institute, Beijing, China. He holds a B.Eng in Electronic Science and Technology from Xi’an Jiaotong University (2020). Bowen specializes in Micro-Electromechanical Systems (MEMS), focusing on resonant accelerometers, bulk acoustic wave gyroscopes, and coupled MEMS resonators. His innovative research includes developing mathematical models for mode-localized resonant accelerometers and pioneering empirical response models for weakly coupled resonators. Bowen has co-authored multiple high-impact journal papers and presented at prestigious conferences like IEEE INERTIAL. His work bridges theoretical exploration with practical applications, advancing MEMS technology and its industrial relevance. Passionate about knowledge dissemination, Bowen actively contributes to the academic community, sharing insights that enhance understanding of emerging MEMS technologies.

Profile

Orcid

Education 🎓

Bowen Wang completed his Bachelor of Engineering (B.Eng) in Electronic Science and Technology at Xi’an Jiaotong University, China, in 2020. Currently, he is pursuing his Ph.D. at the State Key Laboratory of Transducer Technology, Aerospace Information Research Institute, Beijing, China. His academic journey reflects a strong foundation in electronics and a deep dive into advanced MEMS technologies. Bowen’s Ph.D. research focuses on resonant accelerometers, bulk acoustic wave gyroscopes, and coupled MEMS resonators, combining theoretical modeling with experimental validation. His educational background equips him with a robust understanding of both fundamental principles and cutting-edge innovations in MEMS, enabling him to contribute significantly to the field. Bowen’s academic excellence is further demonstrated through his high-impact publications and active participation in international conferences, showcasing his commitment to advancing MEMS research and applications.

Experience 💼

Bowen Wang has gained extensive research experience during his Ph.D. at the State Key Laboratory of Transducer Technology, Aerospace Information Research Institute, Beijing. His work involves designing and optimizing MEMS devices, particularly resonant accelerometers and bulk acoustic wave gyroscopes. Bowen developed innovative mathematical models to predict the behavior of mode-localized resonant accelerometers, establishing the first empirical response model for weakly coupled resonators. He has collaborated on multiple high-impact research projects, resulting in publications in top-tier journals like Micromachines and IEEE Sensors Journal. Bowen has also presented his findings at international conferences, including the IEEE International Symposium on Inertial Sensors and Systems (INERTIAL). His hands-on experience in MEMS fabrication, modeling, and testing has honed his technical expertise, making him a valuable contributor to the field. Bowen’s research bridges theoretical insights with practical applications, driving advancements in MEMS technology.

Awards and Honors 🏆

Bowen Wang has earned recognition for his outstanding contributions to MEMS research. His work on mode-localized resonant accelerometers and weakly coupled resonators has been published in high-impact journals and presented at prestigious conferences like IEEE INERTIAL. Bowen’s innovative research has been acknowledged for its potential to advance MEMS technology, particularly in enhancing sensor sensitivity and performance. His collaborative efforts have resulted in multiple peer-reviewed publications, showcasing his ability to contribute meaningfully to the academic community. While specific awards are not listed, Bowen’s consistent publication record and active participation in international conferences highlight his dedication and excellence in the field. His research has not only deepened the understanding of MEMS principles but also paved the way for practical applications in inertial sensors and systems. Bowen’s achievements reflect his commitment to pushing the boundaries of MEMS technology and its industrial relevance.

Research Focus 🔍

Bowen Wang’s research focuses on advancing Micro-Electromechanical Systems (MEMS), particularly resonant accelerometers, bulk acoustic wave gyroscopes, and coupled MEMS resonators. His work emphasizes mode-localized resonant accelerometers, where he has developed innovative mathematical models to predict device behavior and established the first empirical response model for weakly coupled resonators. Bowen’s research bridges theoretical exploration with practical applications, enhancing sensor sensitivity, performance, and robustness against manufacturing defects. He also investigates novel coupling structures and noise analysis models to optimize MEMS device performance. His contributions have led to high-impact publications and presentations at international conferences, showcasing his ability to address complex challenges in MEMS design and fabrication. Bowen’s research not only deepens the understanding of MEMS principles but also drives advancements in inertial sensors and systems, making significant strides in both academic and industrial applications.

Publication Top Notes📚

  • A Mode-Localized Micro-Electromechanical System Accelerometer with Force Rebalance Closed-Loop Control
  • A Mode-localized Resonant Accelerometer Based on A Novel Micro-lever Coupler Resistant to Manufacture Process Defects
  • Bridging Piezoelectric And Electrostatic Effects: A Novel Pitch/Roll Gyroscope
  • Utilizing Mechanical Micro-lever Coupling Structure to Enhance Sensitivity in Mode-localized MEMS Accelerometer
  • Comparing Different Output Metrics of High-Resolution MEMS Weakly Coupled Resonant Tilt Sensors
  • A Decouple-Decomposition Noise Analysis Model for Closed-loop Mode-localized Tilt Sensors