Hao Zhu | Nanoelectronics | Innovative Research Award

Published on by Electrical Engineering

Innovative Research Award

Hao Zhu
Fudan University, China

Hao Zhu
Affiliation Fudan University
Country China
Scopus ID 55697924500
Documents 238
Citations 5,644
h-index 39
Subject Area Nanoelectronics
Event World Electrical Engineering Awards
Google Scholar z3GiPsoAAAAJ&hl

The Innovative Research Award recognizes sustained scholarly contributions in nanoelectronics and advanced electronic materials. Hao Zhu of Fudan University has established a significant research profile through publications, citations, and interdisciplinary investigations that contribute to the development of next-generation electronic systems and nanotechnology applications.[1]

Abstract

This article presents an overview of Hao Zhu’s academic achievements in nanoelectronics and related electronic engineering disciplines. With an extensive publication record and substantial citation impact, his research has contributed to understanding nanoscale materials, device architectures, and advanced semiconductor technologies. His scholarly activities reflect engagement with emerging challenges in electronic miniaturization, performance optimization, and sustainable technological development. The combination of scientific productivity, interdisciplinary collaboration, and measurable academic influence provides a basis for recognition through the Innovative Research Award within the World Electrical Engineering Awards framework.[1][2]

Keywords

Nanoelectronics, Semiconductor Devices, Electronic Materials, Nanotechnology, Advanced Manufacturing, Electrical Engineering, Research Innovation.

Introduction

Nanoelectronics represents a rapidly advancing field that integrates materials science, physics, and electrical engineering. Researchers working in this domain contribute to the development of smaller, faster, and more efficient electronic systems. Hao Zhu’s academic record demonstrates active participation in these advancements through scholarly research and publication activities.[2]

Research Profile

Affiliated with Fudan University, Hao Zhu has developed a research portfolio characterized by 238 indexed documents, more than 5,600 citations, and an h-index of 39. These indicators suggest sustained academic engagement and visibility within international research communities focused on nanoelectronics and related technological disciplines.[1]

Research Contributions

His contributions include investigations into nanoscale device behavior, advanced materials, and electronic system optimization. Research outputs have supported ongoing discussions regarding device performance, energy efficiency, and emerging fabrication methods. Collaborative studies have further expanded the practical relevance of nanoelectronic technologies in academic and industrial contexts.[3]

Publications

The publication portfolio encompasses journal articles, conference proceedings, and collaborative research papers. These works address semiconductor materials, nanoscale structures, and innovative electronic applications. The breadth of topics demonstrates consistent scholarly productivity and participation in internationally recognized research networks.[4]

Research Impact

Citation metrics indicate that the research has been referenced extensively by other scholars. Such engagement reflects academic influence and suggests that published findings have contributed to subsequent investigations within nanoelectronics and related engineering fields.[1]

Award Suitability

The combination of research productivity, citation performance, interdisciplinary relevance, and international visibility aligns with common evaluation criteria used for innovation-focused academic awards. These characteristics support consideration for recognition through the Innovative Research Award.[5]

Conclusion

Hao Zhu’s scholarly profile reflects sustained contributions to nanoelectronics research. Through extensive publication activity, citation impact, and engagement with emerging technologies, the researcher has established a record consistent with academic excellence and innovation in electrical engineering.

References

  1. Elsevier. (n.d.). Scopus author details: Hao Zhu, Author ID 55697924500. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=55697924500
  2. Google Scholar. (n.d.). Scholar profile and citation metrics.
    https://scholar.google.com/citations?user=z3GiPsoAAAAJ&hl=en
  3. Nature Nanotechnology. (2021). An in-memory computing architecture based on two-dimensional semiconductors for multiply-accumulate operations.
    https://doi.org/10.1038/s41467-021-23719-3
  4. IEEE. (2023). Binary semiconductor In2Te3 for the application of phase-change memory device.
    https://doi.org/10.1007/s10853-010-4401-z
  5. World Electrical Engineering Awards. (n.d.). Award evaluation framework and recognition criteria.
    https://electricalaward.com/

Minghui Liu | Radiation Physics | Research Excellence Award

Published on by Electrical Engineering

Research Excellence Award

Mr. Minghui Liu
Affiliation Naval University of Engineering
Country China
Scopus ID 58298229600
Documents 13
Citations 61
h-index 3
Subject Area Radiation Physics
Event World Electrical Engineering Awards

Minghui Liu is affiliated with the Naval University of Engineering, China, and is recognized for scholarly contributions in the field of radiation physics and related engineering disciplines. His research profile demonstrates active engagement in scientific publication, citation development, and technical investigations associated with radiation-related engineering applications.[1] The academic profile reflects participation in internationally indexed research outputs and professional recognition within electrical and applied engineering communities.[2]

Abstract

This article presents a structured academic recognition overview of Mr. Minghui Liu, whose scholarly activities are associated with radiation physics and engineering-oriented scientific research. The profile reflects indexed publication records, measurable citation activity, and participation in internationally recognized research databases.[1] The article further evaluates publication performance, research visibility, and technical contribution areas associated with engineering-oriented scientific research.

Keywords

Radiation Physics; Electrical Engineering; Scientific Publications; Research Metrics; Citation Analysis; Engineering Research; Academic Recognition; Indexed Journals; Scopus Profile; Applied Physics.

Introduction

Academic recognition systems frequently evaluate researchers based on publication quality, citation performance, interdisciplinary influence, and scientific engagement. Within engineering and applied physics disciplines, researchers contributing to radiation physics support advancements in instrumentation, technical analysis, energy systems, and scientific methodology.[3] Mr. Minghui Liu’s scholarly profile demonstrates measurable participation in these academic areas through indexed publications and citation records available through international research databases.[1]

Professional engineering recognition programs commonly evaluate scholarly consistency, academic visibility, and documented scientific contribution within technical disciplines.

Research Profile

According to indexed academic records, Mr. Minghui Liu has authored or co-authored thirteen scientific documents with a cumulative citation count of sixty-one and an h-index value of three.[1] These metrics indicate measurable scholarly engagement and continued participation in technical research dissemination. The research portfolio is primarily associated with radiation physics and related scientific engineering domains.

Researchers working within engineering and applied scientific institutions frequently contribute to engineering analysis, physical sciences, and advanced technical methodologies relevant to interdisciplinary technological development.

Research Contributions

The available research profile suggests contributions associated with radiation-related engineering analysis, scientific measurement systems, and applied physical methodologies. Radiation physics research plays a significant role in energy systems, materials evaluation, medical instrumentation, and environmental analysis.[3]

Engineering research within radiation-oriented scientific domains commonly requires multidisciplinary integration involving physics, electrical systems, instrumentation, and computational assessment. The publication activity attributed to Mr. Minghui Liu reflects involvement in technical scientific communication and participation in peer-reviewed research dissemination.[2]

Publications

The indexed publication portfolio associated with Mr. Minghui Liu includes scientific works documented in internationally recognized databases. Publication activity serves as an important indicator of research engagement, collaborative participation, and technical communication within academic communities.[1]

Research Impact

Citation indicators and indexed publication visibility provide measurable evidence of academic engagement and technical dissemination. The citation profile associated with Mr. Minghui Liu indicates that the published research has attracted scholarly attention within related scientific communities.[1]

Research impact in radiation physics and engineering frequently extends beyond direct publication metrics and contributes to broader technical applications including instrumentation systems, scientific diagnostics, computational modeling, and engineering design processes.[3] Indexed publications further support academic collaboration and scientific visibility across institutional and international research environments.

Award Suitability

Based on the available scholarly indicators, Mr. Minghui Liu demonstrates characteristics commonly associated with professional engineering recognition programs, including indexed publication activity, measurable citation performance, and subject specialization in radiation physics. The integration of scientific research with engineering-oriented applications aligns with broader objectives related to engineering and applied scientific advancement.

Professional engineering award frameworks generally emphasize scientific contribution, innovation potential, and research dissemination within engineering and technical disciplines. The documented publication and citation profile supports consideration under academic recognition categories relevant to applied physics and engineering sciences.

Conclusion

Mr. Minghui Liu’s academic profile reflects active participation in radiation physics research and indexed scientific publication. The documented metrics, including publication count, citation visibility, and institutional affiliation, indicate measurable scholarly contribution within engineering-related scientific disciplines.[1] The research record demonstrates alignment with professional academic recognition standards associated with engineering excellence and technical research contribution.

References

  1. Elsevier. (n.d.).Scopus author details: Mr. Minghui Liu, Author ID 58298229600. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=58298229600
  2. ORCID. (n.d.).ORCID profile record for Minghui Liu.
    https://orcid.org/0009-0000-8950-4261
  3. Ren, Y., Zhu, M., Liu, Y., Dai, X., Zhao, J., & Liu, M. (2026). Modeling and experimental validation of ELDRS-induced total dose degradation in bipolar transistors. Radiation Physics and Chemistry, 244, 113794.
    https://doi.org/10.1016/j.radphyschem.2026.113794

 

 

Ms. Jingmin Ge | Sensor Networks & Wireless Sensor Technologies | Innovative Research Award

Published on by Electrical Engineering

Ms. Jingmin Ge | Sensor Networks & Wireless Sensor Technologies | Innovative Research Award

Sensors | Zhengzhou university | China

Dr. Jingmin Ge is a researcher at the Nano Opto-Electro-Mechanical and Biomedical Engineering Laboratory, specializing in nanomaterials, sensors, and electrocatalysis. She earned her Ph.D. in Chemistry from Beijing University of Chemical Technology, M.Sc. in Organic Chemistry from Central China Normal University, and B.Sc. in Applied Chemistry from Henan Agricultural University. Dr. Ge has led and contributed to several national and collaborative projects focused on high-performance electrocatalysts, toxic gas and soil sensors, and sustainable environmental monitoring systems. Her research integrates material synthesis, nanostructure design, and DFT simulations to uncover mechanisms in hydrogen evolution, CO₂ reduction, and pollutant detection. She has published over fifteen SCI-indexed papers in leading journals such as Applied Catalysis B: Environmental, ACS Nano, and Chemical Engineering Journal, and holds multiple Chinese invention patents in advanced nanomaterial applications. Recognized for her scientific excellence, Dr. Ge has served as a key contributor in state-level laboratories, advancing green energy and smart sensing technologies. Her professional portfolio demonstrates a sustained commitment to interdisciplinary innovation, bridging theoretical computation and experimental materials science, and positioning her as a distinguished researcher in chemical engineering and nanotechnology. According to Scopus, her research record includes 540 citations across 26 publications with an h-index of 12.

Profile: Scopus

Featured Publications

Ge, Jingmin*, Dual-metallic Single Ru and Ni Atoms Decoration of MoS₂ for High-efficiency Hydrogen Production. Appl. Catal. B-Environ., 2021, 298, 120557.

Ge, Jingmin*, Oxygen Atoms Substituting Sulfur Atoms of MoS₂ to Activate the Basal Plane and Induce Phase Transition for Boosting Hydrogen Evolution. Mater. Today Energy, 2021, 22, 100854.

Ge, Jingmin, Heterostructure Ni₃S₄–MoS₂ with Interfacial Electron Redistribution Used for Enhancing Hydrogen Evolution. RSC Adv., 2021, 11, 19630–19638.

Ge, Jingmin*, Activated MoS₂ by Constructing Single Atomic Cation Vacancies for Accelerated Hydrogen Evolution Reaction. ACS Appl. Mater. Interfaces, 2022, 14, 26846–26857.

Ge, Jingmin, NiFeCu Phosphides with Surface Reconstruction via Topotactic Transformation of Layered Double Hydroxides for Overall Water Splitting. Inorg. Chem. Front., 2023, 10, 3515–3524.