Danhui Zhang | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Danhui Zhang | Materials Science | Best Researcher Award

Linyi University, China

Zhang Danhui is an accomplished associate professor at the School of Mechanical and Vehicle Engineering, Linyi University, with a distinguished background in engineering and nanomaterials research. Since earning her Ph.D. in Engineering from Nanjing University of Science and Technology in 2012, she has developed a robust research portfolio focused on inorganic nanofunctional materials, polymer composites, and carbon-based nanostructures. With over 40 academic publications, more than 30 of which are indexed in SCI, Dr. Zhang has contributed significantly to fields including surface-enhanced Raman scattering, molecular dynamic simulations, and fluorescence sensors. Her dedication to academic excellence is evident in her active participation in national and provincial research projects, authorship of a scientific monograph, and mentorship of student-led research, resulting in SCI papers and patent grants. In addition to her research work, she is a committed educator, delivering core undergraduate and graduate courses across thermodynamics, chemistry, and physics. She has been recognized with multiple awards for academic and instructional excellence, as well as one registered utility model patent. Dr. Zhang continues to be a key figure in applied materials research and education, combining theoretical innovation with practical applications. Her scholarly contributions position her as a leading candidate for research honors at the national level.

Professional Profile

Education

Zhang Danhui completed her doctoral studies in Engineering at Nanjing University of Science and Technology in 2012. Her doctoral research focused on the synthesis, structure, and properties of functional nanomaterials, specifically targeting noble metal and carbon-based composites. The strong academic foundation laid during her Ph.D. studies has equipped her with a deep understanding of both experimental and theoretical aspects of materials engineering. Prior to her doctoral studies, she had acquired a comprehensive background in science and engineering disciplines, including chemistry, materials science, and applied physics. Her education emphasizes interdisciplinary integration, a feature that is clearly reflected in her ongoing research. The curriculum and training received at Nanjing University of Science and Technology, one of China’s top-tier technical institutions, prepared her for a career that bridges molecular science, nanotechnology, and engineering applications. Furthermore, her academic background has been instrumental in enabling her to teach advanced subjects such as Engineering Thermodynamics, University Physics, and Engineering Chemistry. Her educational path reflects a consistent trajectory of scientific rigor, analytical skill development, and innovation—all of which continue to inform and strengthen her research and academic contributions.

Professional Experience

Since July 2012, Zhang Danhui has served as an associate professor at the School of Mechanical and Vehicle Engineering, Linyi University. Over the years, she has developed an impressive teaching and research portfolio. Her professional duties include lecturing core undergraduate and postgraduate courses in Engineering Thermodynamics, Advanced Mathematics, Engineering Chemistry, and University Physics. Beyond her teaching responsibilities, she actively supervises student research and project development. Under her mentorship, students have produced multiple scientific outcomes, including the publication of an SCI-indexed paper and the authorization of a utility model patent. She has led and participated in several significant national and provincial research initiatives, including projects funded by the National Natural Science Foundation of China and the Natural Science Foundation of Shandong Province. Dr. Zhang has also contributed as a co-investigator in studies involving nonlinear dynamics, rod pumping systems, and nanomaterial simulations. Her role at Linyi University underscores a blend of academic instruction, mentorship, and scientific investigation. Her contributions to institutional research and education have been acknowledged through various awards and recognitions, marking her as a key faculty member within her department. Her continuous commitment to science and education exemplifies the standards of academic excellence.

Research Interest

Zhang Danhui’s research interests lie at the intersection of nanotechnology, materials science, and polymer engineering. Her primary focus is on the chemical preparation and structural characterization of inorganic nanofunctional materials. She has explored complex material behaviors at the atomic level through molecular dynamic simulations, particularly focusing on polymer composites and graphene-based structures. Another central area of her work involves the design, synthesis, and application of new carbon materials, such as carbon nanotubes and graphene derivatives, which are known for their potential in electronics, sensors, and energy storage. Her research has extended into surface-enhanced Raman scattering, fluorescence sensors, and the structural formation of hybrid nanomaterials like silver and platinum-coated carbon structures. Her theoretical modeling work, especially in simulating the curling and core-shell formations of carbon nanostructures, has advanced the understanding of their functional properties in applied settings. She combines simulation studies with experimental synthesis, aiming for practical applications in catalysis, optics, and electronics. This dual approach ensures that her work remains both scientifically grounded and technologically relevant. Dr. Zhang’s research is interdisciplinary, combining chemistry, physics, and materials engineering to explore novel material functionalities and applications.

Research Skills

Dr. Zhang Danhui possesses a versatile and advanced skill set in materials research, particularly within the realms of nanomaterials and polymer simulations. Her core skills include chemical synthesis of metallic and carbon-based nanostructures, advanced molecular dynamics simulation, surface functionalization, and nanomaterial characterization. She is proficient in applying computational techniques to study molecular behavior, bonding interactions, and mechanical stability of composite structures. Her experimental capabilities span a range of modern techniques, including Raman spectroscopy, electron microscopy, XRD, and UV-Vis spectroscopy, often used to validate her simulation results. Furthermore, she has expertise in modeling structural transitions and diffusion dynamics at the nanoscale, contributing to predictive understanding in the design of new materials. Her skillset extends into academic writing, scientific reporting, and the preparation of grant proposals, as evidenced by her extensive publication record and successful project leadership. In addition, her experience in supervising research students has enabled her to develop strong mentoring, analytical problem-solving, and collaborative project management skills. She has effectively bridged theoretical and applied research, a rare and valuable competency that enhances the innovation and impact of her scientific work.

Awards and Honors

Zhang Danhui has received multiple honors that reflect her academic excellence and contributions to research and education. She has been recognized with two municipal and departmental awards for outstanding scientific achievements, which underscore the significance and quality of her research output in the field of nanomaterials and materials engineering. Additionally, she earned an Outstanding Instructor Award, highlighting her excellence in academic mentorship and student guidance. These accolades demonstrate not only her ability to conduct high-level research but also her dedication to teaching and capacity to inspire young researchers. Her efforts in guiding student-led projects have led to notable achievements, including a published SCI-indexed paper and an authorized utility model patent, further confirming her strength in nurturing academic growth and innovation. Moreover, she holds a patent titled “An energy-saving power bank”, registered in China (ZL2019 2 0847842.9), reflecting her inclination toward real-world applications of research. Her professional recognition spans both scientific innovation and educational impact, making her a well-rounded scholar. These honors affirm her status as a leading researcher and educator within her institution and beyond, contributing meaningfully to national and regional scientific progress.

Conclusion

Zhang Danhui exemplifies a rare blend of academic excellence, research innovation, and educational commitment. With a strong foundation in engineering and a focused research agenda in nanofunctional materials and polymer composites, she has consistently demonstrated high-impact scientific productivity. Her robust publication record, leadership in funded projects, and expertise in molecular simulations and material synthesis position her as a leading contributor in her field. Beyond research, her dedication to student mentorship and instruction in core engineering subjects underscores her value as an educator. Her work reflects a dynamic integration of theoretical understanding and practical innovation, bridging gaps between computation, experimentation, and application. Recognition through awards, patents, and institutional accolades further attests to her wide-ranging influence. Dr. Zhang’s contributions not only advance the frontiers of nanotechnology and materials science but also help shape the next generation of engineers and researchers. Her professional journey, characterized by dedication, innovation, and impact, makes her an outstanding candidate for prestigious research awards. Moving forward, greater international collaboration and industry engagement could further amplify her global influence and the real-world application of her discoveries. Her career serves as a model of excellence in interdisciplinary research and academic leadership.

Publications Top Notes

1. Self-assembly behaviour of heterocyclic polymers induced by multiple carbon cone molecules

  • Authors: Xiangkang Zhang, Danhui Zhang, Wenqiang Hu, Houbo Yang, Zhongkui Liu, Xiangfei Ji, Dengbo Zhang

  • Year: 2025

  • Journal: Journal of Solid State Chemistry

2. Autonomous assembly behavior of polypyrrole induced by carbon cone[2,3]

  • Authors: Mingchen Gong, Danhui Zhang, Houbo Yang, Liu Yang, Dengbo Zhang, Ruquan Liang, Anmin Liu

  • Year: 2025

  • Journal: Inorganic Chemistry Communications

3. Multiple fullerene C70s induce polyacetylene to form a fish-like structure

  • Authors: Houbo Yang, Danhui Zhang, Ruquan Liang, Chenglei Zhang, Anmin Liu

  • Year: 2021

  • Journal: Solid State Communications

4. Formation of “hemp flowers” structures from polyphenyl induced by C70

  • Authors: Danhui Zhang, Ruquan Liang, Houbo Yang, Yuanmei Song, Jianhui Shi, Dengbo Zhang, Liu Yang, Anmin Liu

  • Year: 2021

  • Journal: Surfaces and Interfaces

5. Formation of Multiple‐Helical Core‐Shell Structure from Polyphenyl and Boron Nitride Nanotube

  • Authors: Houbo Yang, Danhui Zhang, Ruquan Liang, Zhongkui Liu, Yuanmei Song, Liu Yang, Anmin Liu

  • Year: 2021

  • Journal: Advanced Theory and Simulations

6. Research on the Interfacial Interaction between Polyacetylene and Silver Nanowire

  • Authors: Danhui Zhang, Ruquan Liang, Zhongkui Liu, Houbo Yang, Jianhui Shi, Yuanmei Song, Dengbo Zhang, Anmin Liu

  • Year: 2020

  • Journal: Macromolecular Theory and Simulations

7. Molecular dynamics simulations of single-walled carbon nanotubes and polynylon66

  • Authors: Danhui Zhang, Houbo Yang, Zhongkui Liu, Anmin Liu

  • Year: 2019

  • Journal: International Journal of Modern Physics B

Keming Zhang | Materials Science | Breakthrough Research Award

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Dr. Keming Zhang | Materials Science | Breakthrough Research Award

Shanghai for Science and Technology, China

Keming Zhang is an Associate Professor at the School of Mechanical Engineering, University of Shanghai for Science and Technology. With a solid academic background and more than a decade of experience in engineering mechanics and experimental mechanics, he has emerged as a capable researcher in the area of residual stress measurement and deformation analysis techniques. His work demonstrates a deep engagement with the development and refinement of measurement systems and digital image processing methods under complex physical conditions. Dr. Zhang has authored and co-authored multiple research articles published in internationally recognized journals and has contributed to several high-value patents related to stress testing and 3D imaging technologies. His collaborative project with the Commercial Aircraft Corporation of China (COMAC) reflects his capacity to translate scientific knowledge into real-world industrial applications. Known for his systematic and innovative approach, he has also delivered invited talks and earned national awards for academic excellence. Although he has not yet secured national-level funding, his contributions to instrumentation and applied research have made a notable impact in his field. His research continues to support advancements in aerospace testing, smart materials evaluation, and digital measurement systems. Dr. Zhang is regarded as a valuable contributor to China’s applied mechanics research landscape.

Professional Profile

Education

Keming Zhang holds a Ph.D. in Mechanics from Shanghai Jiao Tong University, completed in 2016. His doctoral training provided a strong foundation in theoretical and experimental mechanics, preparing him for independent research in stress analysis and structural evaluation. Prior to his Ph.D., he earned a Master’s degree in Solid Mechanics in 2007 from the University of Science and Technology Beijing, conducted in collaboration with the Institute of Mechanics at the Chinese Academy of Sciences, which further enriched his theoretical understanding of material behavior and structural dynamics. His academic journey began with a Bachelor’s degree in Engineering Mechanics from Shenyang Aerospace University, awarded in 2005. This progressive academic trajectory reflects his long-standing commitment to mastering the core principles of mechanical engineering and applying them to practical research challenges. His education is rooted in institutions known for their rigor and emphasis on engineering innovation, and his exposure to interdisciplinary mechanical studies has allowed him to develop expertise in residual stress measurement, advanced materials testing, and digital deformation analysis. These qualifications collectively form the basis for his work in applied mechanics, preparing him well for both academic roles and industry collaborations.

Professional Experience

Dr. Keming Zhang has accumulated extensive academic and research experience across several prominent institutions in China. Since June 2021, he has served as an Associate Professor in the School of Mechanical Engineering at the University of Shanghai for Science and Technology. Prior to this, he worked as a Lecturer at the same institution from October 2019 to May 2021. Between 2016 and 2019, Dr. Zhang held a position as Assistant Researcher at the Shanghai Institute of Technical Physics, Chinese Academy of Sciences, where he worked on advanced optical and mechanical systems. Earlier in his career, he served as Lecturer (2009–2012) and Teaching Assistant (2007–2009) in the Department of Materials Engineering at Nanchang Hangkong University. These academic roles have allowed him to gain experience in teaching, supervising student research, and contributing to lab-based experimental studies. Although he has not undertaken formal postdoctoral work, his career path reflects steady progression from foundational teaching roles to high-level independent research. His participation in applied projects, such as those commissioned by COMAC, highlights his ability to contribute to both the academic and industrial sectors. Overall, Dr. Zhang’s professional trajectory is marked by versatility, technical depth, and growing leadership in mechanical research.

Research Interests

Dr. Keming Zhang’s research primarily focuses on experimental mechanics, with a particular emphasis on residual stress measurement, digital image correlation (DIC), and advanced deformation analysis techniques under non-standard environments. His interest lies in understanding the mechanical behavior of composite and metallic materials, particularly in aerospace and structural applications, using precise optical and computational methods. One of his core research themes involves improving the accuracy and reliability of the incremental hole-drilling method for residual stress determination, as demonstrated in his recent publications. He also works on the development of luminescent speckle techniques and 3D reconstruction methods tailored for low-light or complex surface conditions. His research spans the theoretical modeling and practical design of measurement systems, especially those applicable to the aerospace and manufacturing industries. Dr. Zhang aims to bridge the gap between traditional material testing methods and modern, high-resolution imaging and analysis tools. He is particularly motivated by real-world engineering problems, leading him to pursue research projects in collaboration with industrial partners. Overall, his work contributes to safer, more accurate mechanical assessment technologies, supporting innovations in both academic research and industry implementation.

Research Skills

Dr. Zhang possesses a well-rounded and sophisticated skill set in experimental mechanics and engineering measurement systems. He is highly proficient in residual stress analysis techniques, particularly the incremental hole-drilling method, which he has refined through theoretical modeling and practical calibration. His capabilities also extend to digital image correlation (DIC), luminescent imaging in dark environments, adaptive phase error correction, and 3D surface reconstruction. These skills are reinforced by his hands-on experience in hardware-software integration for custom measurement systems. His applied research frequently involves developing and testing new methodologies under real-world constraints, such as temperature variability or lack of lighting, and his patents showcase his strength in innovation and system design. Dr. Zhang is also competent in finite element modeling for validation and simulation purposes and has experience collaborating on cross-disciplinary teams in both academic and industry projects. His strong foundation in solid mechanics and engineering physics enables him to link theoretical principles with empirical measurements effectively. Furthermore, his academic writing and publication record suggest strong analytical thinking and technical communication skills. Altogether, his research competencies reflect an ability to design, execute, and evaluate sophisticated mechanical testing procedures with precision and industrial relevance.

Awards and Honors

Dr. Zhang has received several notable recognitions for his research contributions. His earliest accolade dates back to 2007, when he was awarded for an excellent student paper at the 6th China International Nano Technology Symposium, reflecting early promise in interdisciplinary scientific research. In 2016, he received a “Youth Excellent Paper” award from the National Committee on Experimental Mechanics at a nationwide mechanics conference, underscoring his growing reputation in the field. He has been invited to deliver talks at national academic conferences, such as the 16th National Conference on Experimental Mechanics in 2021, where he presented on residual stress testing methods. In addition to academic awards, Dr. Zhang is an inventor on multiple patents granted in China between 2021 and 2024. These include patents related to luminescent speckle techniques, digital imaging error compensation, and advanced stress measurement apparatus. These recognitions demonstrate his dual strengths in theoretical development and practical innovation. His awards from both academic societies and industrial patent offices validate his contributions to both basic and applied research. Although he has not yet received major national funding, his honors reflect consistent acknowledgment of the significance and quality of his work by peers and industry stakeholders alike.

Conclusion

Keming Zhang is a technically capable and industrious researcher whose expertise lies at the intersection of experimental mechanics, optical measurement, and applied instrumentation. Through consistent publication, patenting activity, and industrial collaboration, he has demonstrated the ability to convert complex research concepts into tangible technological solutions. His research addresses practical challenges in the aerospace and manufacturing industries, especially in stress analysis and deformation measurement. While his lack of postdoctoral experience and national-level research funding could be viewed as limitations for top-tier competitive awards, his work’s precision, applicability, and methodological innovation speak strongly in his favor. His role as a sole first author or corresponding author on multiple journal papers, along with his leadership in applied projects and system design, highlight his independence and technical leadership. Dr. Zhang’s research is likely to continue contributing to incremental but impactful advances in mechanical measurement and smart sensing technologies. With broader engagement in international collaborations and increased visibility through national funding programs, he could further strengthen his academic profile. In conclusion, while not yet a breakthrough-level figure in terms of disruptive innovation, Dr. Zhang represents a solid, promising researcher whose applied contributions merit recognition and continued support.

Publication Top Notes

  1. Title: Outlier removal method for the refinement of optically measured displacement field based on critical factor least squares and subdomain division
    Journal: Measurement Science and Technology
    Date: 2022-05-01
    DOI: 10.1088/1361-6501/ac476c
    Contributors: Keming Zhang

  2. Title: A Comparative Study of Fatigue Energy Dissipation of Additive Manufactured and Cast AlSi10Mg Alloy
    Journal: Metals
    Date: 2021-08-12
    DOI: 10.3390/met11081274
    Contributors: Chunxia Yang, Ke Zhu, Yayan Liu, Yusheng Cai, Wencheng Liu, Keming Zhang, Jia Huang

  3. Title: A mixed stabilized finite element formulation for finite deformation of a poroelastic solid saturated with a compressible fluid
    Journal: Archive of Applied Mechanics
    Date: 2020-05
    DOI: 10.1007/s00419-020-01658-7
    Contributors: Keming Zhang

  4. Title: New insights into Fourier analysis on plane and convex holographic gratings for imaging spectrometers
    Conference: 9th International Symposium on Advanced Optical Manufacturing and Testing Technologies: Meta-Surface-Wave and Planar Optics
    Date: 2019
    Contributors: Keming Zhang

  5. Title: On the effective stress law and its application to finite deformation problems in a poroelastic solid
    Journal: International Journal of Mechanical Sciences
    Date: 2019-10
    DOI: 10.1016/j.ijmecsci.2019.105074
    Contributors: Keming Zhang

  6. Title: Enhancement of the absorption and bandwidth of a hybrid metamaterial absorber
    Journal: Results in Physics
    Date: 2019-09
    DOI: 10.1016/j.rinp.2019.102412
    Contributors: Keming Zhang

  7. Title: Design and numerical simulations of a temperature tunable hybrid structure metamaterials
    Journal: Journal of Nanophotonics
    Date: 2019-09-18
    DOI: 10.1117/1.jnp.13.036019
    Contributors: Keming Zhang

  8. Title: Numerical verification of absorption enhancement based on metal array embedded metamaterials
    Journal: Materials Express
    Date: 2019-06-01
    DOI: 10.1166/mex.2019.1492
    Contributors: Keming Zhang

  9. Title: Residual stress release characteristics of hole-drilling determined by in-plane three-directional optical interference moiré
    Journal: Journal of Modern Optics
    Date: 2018-12-15
    DOI: 10.1080/09500340.2018.1506519
    Contributors: Keming Zhang, Yong Li, Min Xu, Youlong Ke

  10. Title: General Calibration Formulas for Incremental Hole Drilling Optical Measurement
    Journal: Experimental Techniques
    Date: 2017
    DOI: 10.1007/s40799-016-0008-x
    Contributors: Zhang, K.; Yuan, M.; Chen, J.

Hadi Hijazi | Materials Science | Best Researcher Award

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Dr. Hadi Hijazi | Materials Science | Best Researcher Award

R&D engineer from CEA LETI, France

Dr. Hadi Hijazi is a postdoctoral researcher specializing in microelectronics and semiconductor nanostructures, with extensive experience in epitaxial growth and device fabrication. Based in Grenoble, France, he has developed a strong academic and research background through work at top-tier institutions such as CEA-LETI, CNRS/LTM, and Saint Petersburg State University. His research encompasses the design, modeling, and experimental development of III-V materials and nanostructures for high-performance optoelectronic devices, including visible and near-infrared LEDs. His doctoral studies focused on the epitaxial growth of GaAs nanowires via HVPE and the investigation of spin and charge transport. Dr. Hijazi possesses deep technical expertise in MOCVD, HVPE, and cleanroom operations, supported by his proficiency in a wide range of characterization tools such as XRD, SEM, AFM, PL, and Raman spectroscopy. In addition to his laboratory capabilities, he is skilled in modeling and simulation using tools like Matlab, Nextnano, and Mathematica. Multilingual and collaborative, Dr. Hijazi has a history of successful international projects, combining both theoretical insight and experimental innovation. His contributions to the field are reflected in quality publications in peer-reviewed journals, and he maintains active connections with research leaders and institutions in France and abroad. He is currently an R&D engineer at CEA LETI, contributing to hybrid bonding technologies.

Professional Profile

Education

Dr. Hadi Hijazi holds a Ph.D. in Physics of Materials from Institut Pascal at Université Clermont Auvergne, France, where he worked on the development of GaAs nanowires grown on Si substrates using hydride vapor phase epitaxy (HVPE). His research addressed charge and spin diffusion in nanowires, integrating fundamental physics with advanced material synthesis techniques. Prior to his doctoral studies, Dr. Hijazi completed a Master’s degree (M2) in Nanoelectronics and Nanotechnology from Université Grenoble Alpes, where he received training in nanoscale materials, semiconductor physics, and cleanroom-based device fabrication. He also holds a Master 1 in Fundamental Physics and Nanoscience from Université Joseph Fourier in Grenoble, which laid the foundation for his later specialization in materials and device engineering. His academic training has been interdisciplinary, with strong emphasis on physics, nanotechnology, materials science, and applied electronics. His formal education has equipped him with theoretical depth and practical skill sets, enabling his contributions to multidisciplinary research involving physical modeling, simulation, and experimental validation of micro- and nanoscale structures. These qualifications have prepared him well for complex problem-solving in research-intensive environments, particularly within the highly competitive field of semiconductor materials and microelectronics.

Professional Experience

Dr. Hadi Hijazi has accumulated a robust portfolio of research and development experience across premier academic and industrial research institutions. Since July 2023, he has been serving as an R&D Engineer at CEA LETI in Grenoble, where he works on hybrid bonding technologies, a critical area for 3D integration in microelectronics. From October 2021 to June 2023, he served as a postdoctoral researcher jointly at CEA-LETI and CNRS/LTM, contributing to the IRT Nanoelec project. During this tenure, he focused on the design and simulation of novel heterostructures using III-(As,P) materials for high-performance visible and NIR LEDs. His work included epitaxial process development (MOCVD) on 300 mm substrates and comprehensive characterization of material and device properties. Prior to this, he was a postdoctoral researcher at ITMO University and Saint Petersburg State University in Russia, focusing on growth modeling of III-V and IV-IV micro/nanostructures. Dr. Hijazi also undertook an industrial internship at CEA LETI in 2016, studying the bonding of refractory metal thin films for 3D technologies. Throughout his career, he has demonstrated the ability to integrate theory, simulation, and fabrication in practical research, aligning well with multidisciplinary goals in microelectronics and optoelectronics innovation.

Research Interests

Dr. Hadi Hijazi’s research interests center around advanced semiconductor materials and their integration into high-performance optoelectronic and microelectronic devices. He is particularly focused on the design, epitaxial growth, and characterization of III-V compound semiconductors on silicon substrates, with the goal of enabling new generations of energy-efficient light sources and integrated photonics. His doctoral work involved HVPE growth of GaAs nanowires on Si(111) substrates, aiming to understand charge and spin transport mechanisms at the nanoscale. His postdoctoral research extended to MOCVD-based fabrication of InGaAs and InP heterostructures for LED applications and included structural and electro-optical characterization. He is also interested in hybrid bonding technologies and 3D integration techniques critical to the future of chip stacking and packaging. Dr. Hijazi combines experimental efforts with simulation and modeling, employing tools like Matlab and Nextnano to optimize nanostructure design and predict growth behavior. He is deeply engaged in the physical understanding of epitaxy, surface/interface interactions, and defect formation. These interests place him at the intersection of materials physics, nanotechnology, and applied engineering, with relevance to optoelectronics, spintronics, and next-generation semiconductor device platforms.

Research Skills

Dr. Hadi Hijazi possesses a comprehensive set of research skills that span theoretical modeling, experimental techniques, and process development in nanotechnology and materials science. His expertise in vapor phase epitaxy, including both MOCVD and HVPE methods, allows him to develop high-quality III-V semiconductor nanostructures on various substrates. He has extensive cleanroom experience and is adept in device fabrication processes, material growth protocols, and post-growth characterization. He is proficient in a range of analytical tools such as XRD, AFM, SEM, Raman spectroscopy, photoluminescence (PL), and electrochemical and C-V measurements. Dr. Hijazi is also skilled in simulation and modeling, using software like Matlab, Mathematica, Nextnano, Python, and C++ to analyze material behaviors and guide experimental design. His strong command of semiconductor physics and nanostructure dynamics supports both fundamental research and practical application development. He is an effective communicator in French, English, and Arabic, and his collaborative approach to research is evident in his successful engagements with multidisciplinary teams across France and Russia. Additionally, his organizational and documentation skills are well-developed, contributing to his ability to manage complex research tasks and publish high-quality scientific articles.

Awards and Honors

While specific named awards are not listed in the available information, Dr. Hadi Hijazi’s inclusion in competitive research programs and positions at prestigious institutions such as CEA-LETI, CNRS, and ITMO University itself serves as recognition of his capabilities and achievements. His acceptance into highly selective doctoral and postdoctoral programs in France and Russia, coupled with his contributions to projects such as IRT Nanoelec, suggests a high degree of merit and recognition by the scientific community. His publications in internationally recognized journals such as Nanotechnology and Journal of Physical Chemistry C also indicate the quality and impact of his research. Furthermore, his involvement in international collaborations and multidisciplinary research teams demonstrates the professional trust placed in his expertise and reliability. His continuing employment at CEA LETI in a research and development role is itself a form of institutional endorsement, affirming his value in the innovation ecosystem of advanced microelectronics. With further dissemination of his work and engagement in academic presentations or grant-funded leadership, it is likely he will accrue formal honors and awards in the near future.

Conclusion

Dr. Hadi Hijazi is an accomplished early-career researcher with strong potential for further growth in the field of semiconductor nanotechnology and microelectronics. His academic training and international research experience have equipped him with both depth and versatility, enabling contributions to next-generation devices through innovations in epitaxial growth, material design, and device integration. His ability to bridge theoretical modeling with experimental realization is a key asset, particularly in collaborative research environments. While his current achievements position him as a valuable team member and emerging expert, more visible research leadership, independent project development, and broader dissemination of research outputs could further strengthen his candidacy for major research awards. At present, Dr. Hijazi would be an ideal candidate for recognitions aimed at emerging scientists or rising researchers, and with continued productivity and impact, he is well-poised to become a leading figure in semiconductor device research. His technical expertise, commitment to quality, and collaborative ethos make him a noteworthy contributor to academic and industrial R&D. As he continues his career at CEA LETI and beyond, further contributions in both applied technologies and fundamental science can be expected.

Publications Top Notes

  1. Fine Pitch Superconducting Interconnects Obtained with Nb–Nb Direct Bonding

  • Authors: Candice M. Thomas, Pablo Renaud, Meriem Guergour, Edouard Deschaseaux, Christophe Dubarry, Jennifer Guillaume, Elisa Vermande, Alain Campo, Frank Fournel, Hadi Hijazi, Anne-Marie Papon, Catherine Pellissier, Jean Charbonnier

  • Publication Year: 2025

2. Is NaOH Beneficial to Low Temperature Hybrid Bonding Integration?

  • Authors: Hadi Hijazi¹, Paul Noël¹, Samuel Tardif², Karine Abadie¹, Christophe Morales¹, Frank Fournel¹

  • Publication Date: October 30, 2024