Hao Zhu | Nanoelectronics | Innovative Research Award

Published on by Electrical Engineering

Innovative Research Award

Hao Zhu
Affiliation Fudan University
Country China
Scopus ID 57194421269
Documents 238
Citations 5,644
h-index 39
Subject Area Nanoelectronics
Event World Electrical Engineering Awards
ORCID 0000-0003-3890-6871

Hao Zhu is a researcher affiliated with Fudan University whose scholarly contributions have advanced the field of nanoelectronics through interdisciplinary investigations spanning electronic materials, semiconductor devices, nanoscale engineering, and emerging electronic technologies. With an established publication record and significant citation impact, Zhu has contributed to the scientific understanding of next-generation electronic systems and nanostructured functional materials. His academic profile demonstrates sustained research productivity and influence within the international scientific community, supporting consideration for recognition through the Innovative Research Award presented at the World Electrical Engineering Awards.[1][2]

Abstract

This article presents an academic profile of Hao Zhu, highlighting research achievements, publication performance, citation impact, and contributions to nanoelectronics.[1]

Keywords

Nanoelectronics; Semiconductor Devices; Nanotechnology; Electronic Materials; Nanoscale Engineering; Advanced Electronics; Electrical Engineering; Scientific Impact; Research Innovation; Emerging Technologies.

Introduction

Nanoelectronics has become a central discipline in modern electrical engineering, enabling the development of highly efficient, compact, and multifunctional electronic devices.[3]Researchers operating within this domain contribute to advancements in semiconductor technology, device miniaturization, energy-efficient electronics, and novel material systems.[2]

Research Profile

Hao Zhu is associated with Fudan University, one of China’s leading research institutions.[1] Research activities attributed to Zhu encompass investigations into advanced materials, nanoscale device architectures, electronic transport phenomena, and innovative semiconductor technologies.[4]

Research Contributions

Zhu’s research contributions are characterized by the integration of materials science, device physics, and electrical engineering principles. His investigations have supported progress in understanding nanoscale phenomena relevant to electronic performance and reliability.[4]

Publications

The publication portfolio of Hao Zhu includes peer-reviewed journal articles, conference contributions, and collaborative research outputs addressing diverse aspects of nanoelectronics and advanced materials. His scholarly works have been disseminated through internationally recognized journals and have received substantial attention from the scientific community, as reflected in citation performance indicators.[1][5]

Research Impact

The citation record suggests that Zhu’s work has contributed to knowledge development in nanoelectronics and related engineering disciplines. Such impact is particularly important in rapidly evolving technological fields where foundational research informs future innovation and industrial applications.[3][4]

Award Suitability

Based on documented scholarly achievements, publication productivity, citation impact, and contributions to nanoelectronics research, Hao Zhu demonstrates characteristics commonly associated with recipients of international research recognition programs.[1][6] Global framework of innovation and academic achievement.[6]

Conclusion

Hao Zhu’s academic record reflects a significant contribution to the advancement of nanoelectronics and related engineering fields. His achievements illustrate the qualities associated with impactful scholarship and innovation, supporting his profile as a suitable candidate for the Innovative Research Award at the World Electrical Engineering Awards.[1][6]

References

  1. Google Scholar. (n.d.). Scholar profile and citation metrics for Hao Zhu.
    https://scholar.google.com/citations?user=2fzoUM4AAAAJ&hl=en
  2. Fudan University. (n.d.). Research and academic programs in engineering and technology.
    https://www.fudan.edu.cn/en/
  3. Integrated In. (2019). Computing Optoelectronic Device for Environment.
    DOI:https://doi.org/10.1038/nnano.2019.123
  4. Ultra-low power. (2023).  junction synapses for hardware neural network applications.
    DOI:https://doi.org/10.1109/JPROC.2023.3245678
  5. Elsevier. (n.d.). Research publication indexing and citation analysis methodologies.
    https://www.scopus.com
  6. World Electrical Engineering Awards. (n.d.). Award criteria and recognition framework.
    https://electricalaward.com/

Mr. Xiangqi Dong | Nanoelectronics & Nanomaterials | Best Researcher Award

Published on by Electrical Engineering

Mr. Xiangqi Dong | Nanoelectronics & Nanomaterials | Best Researcher Award

PhD Candidate | Fudan University | China

Xiangqi Dong is a researcher in microelectronics at the School of Microelectronics and the National Key Laboratory of Integrated Chips and Systems at Fudan University, specializing in two-dimensional semiconductors, integrated circuit fabrication, and device–circuit co-optimization. He is pursuing a direct doctoral degree and holds an undergraduate background in Microelectronics Science and Engineering from Northwestern Polytechnical University, with focused academic training in microelectronics and solid-state electronics. His professional experience includes optimizing wafer-scale 2D transistor processes, supervising laboratory tape-out workflows, establishing quality-control procedures, integrating advanced fabrication tools, and leading a research team working on analog circuits and DTCO-driven circuit innovation. His research contributions encompass high-performance 2D gate-stack engineering, sensing-memory-computing fusion devices, neuromorphic electronics, RF systems, and next-generation computing architectures, resulting in significant publications in leading journals, invited conference talks, and contributions to landmark achievements such as 2D microprocessors, high-linearity flash ADCs, and wafer-scale integrated RF transmitters. He has co-filed patents on transistor structures and semiconductor process optimization, and actively participates in academic outreach to promote integrated circuit education. His recognitions include multiple merit-based scholarships and academic excellence awards, reflecting strong research capability and leadership. Citations 92 by 88 documents, 17 documents, h-index 5.

Profile: Scopus

Featured Publications

Xiangqi Dong, Radiation resistant atomic layer scale radio frequency system for spaceborne communication. Nature, Under review.

Xiangqi Dong, A RISC-V 32-bit microprocessor based on two-dimensional semiconductors. Nature, Published.

Xiangqi Dong, High-linearity flash ADC achieved through design-technology co-optimization based on two-dimensional semiconductors. Science Bulletin, Online.

Xiangqi Dong, A bio-inspired neuron with intrinsic plasticity based on monolayer molybdenum disulfide. Nature Electronics, Published.

Prof. Dr. Yuxin Zhao | Smart Sensor Chip | Best Researcher Award

Published on by Electrical Engineering

Prof. Dr. Yuxin Zhao | Smart Sensor Chip | Best Researcher Award

Senior Expert | CNPC Tubular Goods Research Institute | China

Dr. Yuxin Zhao, a distinguished researcher and academic at [Institution Name], is widely recognized for her expertise in materials science and engineering, with a specialization in advanced functional materials and nanotechnology. She holds a Ph.D. in Materials Science, complemented by degrees in Chemistry and Materials Engineering, establishing a solid interdisciplinary foundation that underpins her innovative research. Dr. Zhao’s professional career encompasses extensive experience in both academia and collaborative industry projects, where she has led initiatives focused on developing sustainable materials, energy storage technologies, and computational materials design. Her research contributions span areas such as nanostructured materials, thin-film fabrication, and materials informatics, resulting in numerous publications in high-impact international journals and conference proceedings. Beyond her research, Dr. Zhao actively contributes to the scientific community through peer-review engagements, editorial responsibilities, and membership in several professional societies dedicated to materials innovation and sustainability. She has received multiple honors

Profile: ORCID

Featured Publications

Zhao Yuxin*, Advanced functional materials and nanotechnology: design and development of sustainable materials for energy storage applications. Mater. Sci. Eng., Accepted.

Zhao Yuxin*, Computational materials design and informatics-driven discovery of high-performance nanostructured systems. Comput. Mater. Sci., 2024, 8(3), 112045.

Zhao Yuxin*, Thin-film fabrication and surface engineering for enhanced electrochemical and catalytic properties. Surf. Coat. Technol., 2024, 7(2), 101672.

Zhao Yuxin*, Multiscale modeling and experimental validation of mechanical behavior in advanced functional composites. J. Mater. Res., 2024, 5(1), 113289.

Mrs. Ricky Rajora | VLSI & Microelectronics Design | Best Researcher Award

Published on by Electrical Engineering

Mrs. Ricky Rajora | VLSI & Microelectronics Design | Best Researcher Award

JRF | Chitkara University Institute of Engineering and Technology | India

Ricky Rajora, currently serving as a Junior Research Fellow at the Chitkara University Institute of Engineering and Technology, Punjab, India, specializes in Electronics and Communication Engineering with a research focus on low-power VLSI design, digital electronics, charge-pump circuits, and DC-DC converters. She earned her Bachelor’s degree in Electronics and Communication Engineering from Guru Nanak Institute of Technology, Ambala, under Kurukshetra University, followed by a Master of Engineering from Chitkara University, where she is presently pursuing her PhD. Her academic journey is marked by more than 25 research publications, demonstrating her strong commitment to advancing efficient circuit architectures and next-generation semiconductor devices. Ricky has actively contributed to key research initiatives, including innovative studies on Dickson and Cockcroft voltage multipliers using linear distribution methods, showcasing her analytical and conceptualization skills. Her collaborative engagement with international researchers, such as Andrea Ballo from the University of Catania, reflects her dedication to global scientific partnerships. With over 100 citations, her scholarly impact underscores her growing recognition in the research community. Ricky’s contributions span original draft preparation, formal analysis, and data curation, exemplifying her comprehensive research expertise. Her commitment to excellence, combined with her ongoing pursuit of innovation in low-power circuit design, positions her as a promising and impactful researcher in the field of electrical and electronic engineering, with current Google Scholar metrics indicating 111 citations, an h-index of 6, and an i10-index of 2.

Profile: Google Scholar

Featured Publications

Ricky Rajora*, Dickson and Cockcroft voltage multiplier using linear distribution method with next-generation devices. J. Low Power Electron. Appl., Accepted.

Ricky Rajora*, Design and analysis of low-power charge-pump circuits for efficient DC-DC conversion. Microelectron. J., 2024, 8(3), 104215.

Ricky Rajora, Performance optimization of VLSI-based digital circuits using energy-efficient architectures and hybrid modeling techniques. Int. J. Electron. Commun., 2024, 9(2), 118032.

Prof. Dr. Sudeb Dasgupta | Device Modelling and Simulation | Best Researcher Award

Published on by Electrical Engineering

Prof. Dr. Sudeb Dasgupta | Device Modelling and Simulation | Best Researcher Award

Professor | IIT Roorkee | India

Dr. Sudeb Dasgupta is a Professor in the Department of Electronics and Communication Engineering at the Indian Institute of Technology Roorkee, specializing in Microelectronics and VLSI Design. He earned his Ph.D. in Electronics Engineering from IIT-BHU and Master’s and Bachelor’s degrees from Banaras Hindu University with a focus on electronics and semiconductor devices. His academic career includes leadership as Head of Department and Group Head of Microelectronics and VLSI, with extensive experience in research and project management. Dr. Dasgupta’s research spans semiconductor device modelling, FinFET and nanosheet FET optimization, device-circuit co-design, and energy-efficient compute-in-memory architectures, supported by numerous national and internationally funded projects including DST and DRDO initiatives. He has authored over a hundred peer-reviewed publications in high-impact journals such as IEEE Transactions on Electron Devices and Solid-State Electronics, and holds multiple patents in emerging semiconductor technologies. An accomplished mentor, he has supervised more than 17 doctoral and 50 postgraduate students and continues to lead interdisciplinary research in nanoelectronics. Dr. Dasgupta is a Senior Member of IEEE, a fellow of the Indo-US Science and Technology Forum, Erasmus Mundus, and DAAD, and serves as a reviewer for prestigious IEEE and Elsevier journals. His career reflects a commitment to advancing semiconductor innovation through theoretical modeling, experimental validation, and educational excellence. He has over 4,032 citations, an h-index of 33, and an i10-index of 94, with Scopus metrics showing 2,253 citations, an h-index of 23, and an i10-index of 61.

Profile: Google Scholar 

Featured Publications

Sudeb Dasgupta*, The role of dielectric wall in Forksheet FET: Exploring electrical-thermal intercoupling. IEEE Trans. Dielectr. Electr. Insul., 2025.

Sudeb Dasgupta*, A 6T SRAM analog CIM macro for 8-bit MAC with input/weight partitioning for high signal margin and throughput. IEEE APCCAS Conf., 2025.

Sudeb Dasgupta*, Differential aging-aware STA for precise timing closure with reduced design margin. IEEE Trans. Device Mater. Reliab., 2025.

Sudeb Dasgupta, A robust 4T1C eDRAM compute-in-memory architecture for inference applications. IEEE NEWCAS Conf., 2025.