Tag: Young Researcher in Materials Science

Qijing Wang | Materials Science | Best Researcher Award

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Assist. Prof. Dr. Qijing Wang | Materials Science | Best Researcher Award

Assistant Professor from Nanjing University, China

Dr. Qijing Wang is a dedicated and rapidly emerging scholar in the field of organic electronics. Currently serving as an Assistant Professor at the School of Integrated Circuits, Nanjing University, he has quickly built a reputation for impactful research in charge transport and device physics, particularly in organic field-effect transistors (OFETs). His academic journey has been marked by continuous excellence, with all degrees obtained from the prestigious Nanjing University. Dr. Wang’s scholarly work reflects a deep understanding of electronic science and its applications in advanced materials and device engineering. He has authored several high-impact publications in internationally recognized journals such as Advanced Functional Materials, Small Methods, and ACS Applied Materials & Interfaces. Additionally, his commitment to international collaboration was evident through his postdoctoral research at the University of Cambridge, where he worked under Prof. Henning Sirringhaus. Dr. Wang’s achievements have been recognized through competitive fellowships and national awards, making him a strong candidate for research excellence honors. His career reflects a balanced blend of theoretical knowledge, experimental proficiency, and innovation. As a young academic, Dr. Wang exemplifies the qualities of a future leader in his field, contributing meaningfully to both the academic community and technological advancement in integrated circuits.

Professional Profile

Education

Dr. Qijing Wang received his formal education entirely at Nanjing University, one of China’s premier institutions for science and engineering. He earned his Bachelor of Science degree in Physics in 2012, laying a robust foundational understanding of physical principles that later supported his advanced research in electronics. Building upon his undergraduate education, he pursued a doctoral degree in Electronic Science and Technology at the same university, completing his Ph.D. in 2018. His doctoral studies focused on charge transport mechanisms and the performance enhancement of organic field-effect transistors (OFETs), a research area that positioned him to contribute to cutting-edge developments in organic electronics. Throughout his education, Dr. Wang demonstrated not only academic excellence but also an ability to integrate theoretical physics with practical device engineering. His time as a student at Nanjing University allowed him access to state-of-the-art laboratories, advanced instrumentation, and renowned faculty mentors. These resources equipped him with the skills necessary for conducting high-quality research and developing independent scientific thought. His educational background provides a strong interdisciplinary framework, combining elements of physics, materials science, and electronics, which continues to underpin his professional and academic accomplishments today.

Professional Experience

Dr. Qijing Wang currently serves as an Assistant Professor at the School of Integrated Circuits, Nanjing University. His academic appointment follows a successful tenure as a postdoctoral researcher, during which he significantly contributed to projects on the charge transport and structural optimization of organic semiconductors. As a postdoctoral fellow at Nanjing University, he was selected for the Postdoctoral Innovative Talent Support Program Grant—a highly competitive national program recognizing early-career researchers with exceptional promise. This achievement underscores his ability to undertake independent, innovative research in electronic materials. Further expanding his academic horizon, Dr. Wang spent a period as a visiting postdoctoral researcher at the University of Cambridge, collaborating with Prof. Henning Sirringhaus, a global authority in organic electronics. This international experience enhanced his expertise and enabled cross-border academic engagement. In his current role, Dr. Wang is involved in both teaching and research, mentoring undergraduate and graduate students while leading projects that address challenges in next-generation transistor design. His professional experience reflects a clear progression from student to postdoctoral scholar to independent academic, marked by increasing responsibility, international collaboration, and recognized contributions to the scientific community.

Research Interests

Dr. Qijing Wang’s research interests lie primarily in the field of organic electronics, with a specific focus on charge transport and device physics in organic field-effect transistors (OFETs). He is deeply engaged in exploring the fundamental physical mechanisms that govern the performance of organic semiconductors, aiming to enhance their electronic properties for real-world applications. His work bridges the gap between materials science and circuit-level engineering, addressing both theoretical and experimental challenges. Dr. Wang is particularly interested in the molecular engineering of organic materials to improve charge mobility, stability, and environmental compatibility of OFETs. Additionally, his research encompasses the interface physics between organic materials and metal contacts, dielectric engineering, and nanoscale fabrication techniques. With a growing interest in flexible and wearable electronics, Dr. Wang’s work is increasingly interdisciplinary, contributing to the development of next-generation electronics with applications in healthcare, consumer electronics, and energy devices. His research trajectory demonstrates a commitment to pushing the boundaries of what is possible in organic semiconductors, offering valuable insights into material-device correlations and design strategies. This integrated approach has enabled him to publish in top-tier journals and positions him as a key contributor to the evolution of high-performance, low-cost electronic devices.

Research Skills

Dr. Qijing Wang possesses a comprehensive set of research skills that enable him to excel in the field of organic electronics. His expertise spans both experimental and theoretical domains, particularly in charge transport phenomena, thin-film transistor fabrication, and organic material characterization. He is skilled in using advanced characterization techniques such as atomic force microscopy (AFM), scanning electron microscopy (SEM), and X-ray diffraction (XRD) to analyze material morphology and structure. In terms of electrical performance, he is proficient in using probe stations and semiconductor parameter analyzers for the precise evaluation of transistor characteristics. Dr. Wang also demonstrates strong competencies in molecular design and solution processing techniques, including spin-coating and inkjet printing, which are essential for developing high-performance OFETs. During his postdoctoral research, he honed his ability to conduct independent experiments, manage collaborative projects, and analyze complex data sets. His international research experience at the University of Cambridge also strengthened his adaptability, scientific communication, and teamwork abilities. Furthermore, he is well-versed in using software tools for data modeling, statistical analysis, and device simulation. These technical proficiencies, combined with his innovative mindset, make him a versatile researcher capable of addressing diverse challenges in materials science and device engineering.

Awards and Honors

Dr. Qijing Wang has received notable recognition for his academic and research excellence early in his career. Among his most prestigious honors is the Postdoctoral Innovative Talent Support Program Grant, awarded during his tenure as a postdoctoral fellow at Nanjing University. This national-level fellowship is one of the most competitive and selective programs in China, aimed at identifying and supporting highly promising early-career researchers. Receiving this grant not only highlights Dr. Wang’s research potential but also affirms his capacity to drive independent and impactful scientific inquiries. His selection for a Visiting Postdoctoral Researcher position at the University of Cambridge further underscores his standing in the academic community. This opportunity allowed him to collaborate with leading researchers in organic electronics and broaden his research capabilities in an international environment. In addition to these distinctions, Dr. Wang’s work has been featured in high-impact journals, signaling peer recognition and scholarly merit. These awards and honors are not only commendations of past achievements but also indicators of his future contributions to science and technology. They reflect his ongoing dedication to innovation, academic excellence, and leadership in the field of organic electronic devices.

Conclusion

In summary, Dr. Qijing Wang stands out as an accomplished and innovative researcher in the domain of organic electronics. His academic foundation, built at Nanjing University, has been enriched through nationally and internationally recognized research experiences. With a focus on organic field-effect transistors, he has made significant strides in understanding and optimizing charge transport mechanisms, contributing valuable knowledge to both academia and industry. His achievements, including high-impact publications and prestigious fellowships, highlight his commitment to scientific rigor and originality. Dr. Wang combines deep technical expertise with a collaborative and forward-thinking approach, evidenced by his research visit to the University of Cambridge and active engagement in interdisciplinary projects. While still early in his academic career, he has shown the qualities of a future leader—innovative thinking, strong communication skills, and a clear vision for advancing technology. Continued emphasis on research leadership roles, mentorship, and broader application of his findings will further enhance his impact. Overall, Dr. Wang is a highly deserving candidate for the Best Researcher Award, with demonstrated excellence and the potential for continued breakthroughs in electronic materials and device research.

Publications Top Notes

  • Additive-assisted “metal-wire-gap” process for N-type two-dimensional organic crystalline films
    Authors: Yang, C.; Qian, J.; Wang, Q.; Jiang, S.; Duan, Y.; Wang, H.; Dai, H.; Li, Y.
    Year: 2019

  • PJ-Level Energy-Consuming, Low-Voltage Ferroelectric Organic Field-Effect Transistor Memories
    Authors: Pei, M.; Qian, J.; Jiang, S.; Guo, J.; Yang, C.; Pan, D.; Wang, Q.; Wang, X.; Shi, Y.; Li, Y.
    Year: 2019

  • Two-dimensional organic materials and their electronic applications
    Authors: Wang, H.; Wang, Q.; Li, Y.
    Year: 2019

  • Interfacial Flat-Lying Molecular Monolayers for Performance Enhancement in Organic Field-Effect Transistors
    Authors: Wang, Q.; Jiang, S.; Qiu, L.; Qian, J.; Ono, L.K.; Leyden, M.R.; Wang, X.; Shi, Y.; Zheng, Y.; Qi, Y. et al.
    Year: 2018

  • Millimeter-Sized Two-Dimensional Molecular Crystalline Semiconductors with Precisely Defined Molecular Layers via Interfacial-Interaction-Modulated Self-Assembly
    Authors: Jiang, S.; Qian, J.; Duan, Y.; Wang, H.; Guo, J.; Guo, Y.; Liu, X.; Wang, Q.; Shi, Y.; Li, Y.
    Year: 2018

  • Spin-Coated Crystalline Molecular Monolayers for Performance Enhancement in Organic Field-Effect Transistors
    Authors: Wang, Q.; Juarez-Perez, E.J.; Jiang, S.; Qiu, L.; Ono, L.K.; Sasaki, T.; Wang, X.; Shi, Y.; Zheng, Y.; Qi, Y. et al.
    Year: 2018

  • Temperature dependence of piezo- and ferroelectricity in ultrathin P(VDF-TrFE) films
    Authors: Qian, J.; Jiang, S.; Wang, Q.; Yang, C.; Duan, Y.; Wang, H.; Guo, J.; Shi, Y.; Li, Y.
    Year: 2018

  • Unveiling the piezoelectric nature of polar α-phase P(VDF-TrFE) at quasi-two-dimensional limit
    Authors: Qian, J.; Jiang, S.; Wang, Q.; Zheng, S.; Guo, S.; Yi, C.; Wang, J.; Wang, X.; Tsukagoshi, K.; Shi, Y. et al.
    Year: 2018

  • Directly writing 2D organic semiconducting crystals for high-performance field-effect transistors
    Authors: Zhang, Y.; Guo, Y.; Song, L.; Qian, J.; Jiang, S.; Wang, Q.; Wang, X.; Shi, Y.; Wang, X.; Li, Y.
    Year: 2017

  • Low-voltage, High-performance Organic Field-Effect Transistors Based on 2D Crystalline Molecular Semiconductors
    Authors: Wang, Q.; Jiang, S.; Qian, J.; Song, L.; Zhang, L.; Zhang, Y.; Zhang, Y.; Wang, Y.; Wang, X.; Shi, Y. et al.
    Year: 2017

Jian-gang Guo | Materials Science | Best Researcher Award

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Prof. Dr. Jian-gang Guo | Materials Science | Best Researcher Award

Professor at Institute of Physics Chinese Academy of Sciences: Chinese Academy of Sciences Institute of Physics, China

Jian-gang Guo is a renowned physicist specializing in condensed matter physics, particularly in superconductivity and magnetic materials. He is a Full Professor at the Institute of Physics, Chinese Academy of Sciences (IOP, CAS). His research has significantly contributed to understanding strongly electron-correlated systems, with a focus on superconducting materials. One of his most notable achievements is the discovery of KxFe2Se2 high-temperature superconductors, which opened a new research field and gained worldwide recognition. He has published 118 papers in prestigious journals such as Nature, Nature Chemistry, Nature Communications, and Physical Review Letters. His work has had a profound impact on materials science and has inspired extensive global research. Additionally, he has successfully developed cubic silicon carbide (SiC) single crystals applicable for mass production. His contributions have earned him several prestigious awards, including the Second Prize of the State Natural Science Award of China. With international experience from institutions such as Rice University and the Tokyo Institute of Technology, he has established himself as a leader in superconductivity research. His innovative discoveries, extensive publication record, and international collaborations position him as a highly influential figure in modern condensed matter physics.

Professional Profile

Education

Jian-gang Guo has an extensive academic background in condensed matter and solid-state physics. He earned his Ph.D. in Condensed Matter Physics from the Institute of Physics, Chinese Academy of Sciences (IOP, CAS) in 2011. His doctoral research focused on the properties of electron-correlated materials, particularly superconductors. Prior to his Ph.D., he completed an M.S. in Condensed Matter Physics in 2008 at the State Key Laboratory of Superhard Materials, Jilin University, China. During his master’s studies, he gained expertise in high-pressure physics and material synthesis techniques. He obtained his B.S. in Solid-State Physics from the Department of Physics, Jilin University, in 2005. His undergraduate studies laid the foundation for his later work in electronic materials and crystallography. Throughout his academic journey, he has developed a strong theoretical and experimental background in superconductivity, transport properties, and magnetic interactions. His education at top institutions in China provided him with a solid platform to contribute significantly to the field of condensed matter physics. His ability to integrate fundamental physics with experimental discoveries has made him a key figure in the study of superconducting and magnetic materials.

Professional Experience

Jian-gang Guo has held several prominent academic and research positions in leading institutions worldwide. He is currently a Full Professor at the Institute of Physics, Chinese Academy of Sciences (IOP, CAS), a position he has held since September 2020. Before that, he was an Associate Professor at IOP, CAS, from 2016 to 2020, contributing to advancements in superconductivity and quantum materials. From 2014 to 2016, he was an ICAM Postdoctoral Fellow at the Department of Physics & Astronomy at Rice University, working in Prof. Pengcheng Dai’s group on neutron diffraction studies of magnetic materials. Between 2011 and 2014, he worked as a Postdoctoral Researcher at the Frontier Research Center, Tokyo Institute of Technology, under Prof. Hideo Hosono, where he expanded his expertise in novel superconducting materials. His career has been marked by international collaborations, interdisciplinary research, and groundbreaking discoveries in the field of condensed matter physics. His professional experience has allowed him to develop a strong research network and contribute significantly to both experimental and theoretical advancements in strongly correlated electronic systems.

Research Interests

Jian-gang Guo’s research primarily focuses on the physical properties of strongly electron-correlated systems, including superconductors and magnetic materials. His work involves techniques such as x-ray and neutron diffraction, low-temperature transport measurements, and theoretical modeling. He is particularly interested in exploring the relationship between crystallographic structures and electronic properties in new functional materials. One of his most significant contributions is the discovery of KxFe2Se2 high-temperature superconductors, which led to the development of a new class of alkali-metal intercalated FeSe superconductors. His research has also extended to the growth of bulk cubic silicon carbide (SiC) single crystals using high-temperature solution methods, making them suitable for industrial applications. His interests further include studying charge density waves, metal-insulator transitions, and novel quantum materials. By combining experimental and theoretical approaches, he aims to develop new materials with unique electronic and magnetic properties. His work continues to drive advancements in fundamental physics while also providing potential applications in energy storage, quantum computing, and semiconductor industries.

Research Skills

Jian-gang Guo possesses a diverse set of research skills that enable him to make significant contributions to condensed matter physics. His expertise includes x-ray and neutron diffraction techniques, which he utilizes to investigate the structural and electronic properties of superconductors and magnetic materials. He is skilled in low-temperature transport measurements, allowing him to analyze the electrical and thermal behavior of materials under extreme conditions. His experience in growing high-quality single crystals, including superconducting and semiconducting materials, has been instrumental in developing new materials for both fundamental and applied research. Additionally, he has a strong background in theoretical calculations, enabling him to model electronic structures and magnetic interactions in complex systems. His ability to integrate experimental and computational methods has allowed him to uncover new physical phenomena in strongly correlated materials. Furthermore, his experience with high-pressure synthesis techniques has contributed to the discovery of novel superconducting and magnetic materials. His research skills have been critical in advancing knowledge in condensed matter physics and developing materials with real-world applications.

Awards and Honors

Jian-gang Guo has received several prestigious awards in recognition of his outstanding contributions to condensed matter physics. In 2020, he was awarded the Second Prize of the State Natural Science Award of the People’s Republic of China, one of the highest honors for scientific research in the country. This award recognized his pioneering work on alkali-metal intercalated FeSe superconductors. In 2022, he received the Second Prize of the Beijing Municipal Natural Science Prize, highlighting his impact on superconductivity research. Additionally, he was honored with the CAS Science and Technology Promotion Development Award in 2021 for his contributions to material synthesis and characterization. His research has been widely acknowledged, with his work on high-temperature superconductors being selected as a Milestone Paper for the 50th Anniversary of Physical Review B. These accolades reflect his significant influence on the scientific community and his role in advancing the understanding of strongly correlated electron systems. His continued contributions to superconductivity and novel materials research further solidify his reputation as a leading figure in his field.

Conclusion

Jian-gang Guo is a distinguished researcher whose work has had a transformative impact on condensed matter physics. His discovery of KxFe2Se2 high-temperature superconductors has influenced global research, inspiring over 300 teams worldwide. With 118 publications in top-tier journals and numerous prestigious awards, he has established himself as a leader in superconductivity and materials science. His ability to integrate experimental and theoretical approaches has led to the discovery of novel quantum materials and superconducting compounds. His contributions extend beyond fundamental research, as demonstrated by his work on silicon carbide single crystals, which have industrial applications. His extensive international collaborations, research skills, and ability to mentor young scientists further strengthen his profile. While his work has already made significant contributions to physics, expanding interdisciplinary research into quantum computing, energy materials, and industrial partnerships could further enhance his influence. His achievements, dedication, and pioneering discoveries make him a strong candidate for the Best Researcher Award. His continued research is expected to shape the future of superconductivity, quantum materials, and electronic devices for years to come.

Publications Top Notes

  1. Modeling and Suppressing Interfacial Instability in Growth of SiC from High-Temperature Solutions

    • Authors: Sheng Da, Wang Guobin, Yang Yunfan, Wang Wenjun, Chen Xiaolong
    • Year: 2025

  2. Size-Effect Enriched Phase Diagram in p-Type Skutterudite Superconductor Ir₃.₈Sb₁₂

    • Authors: Wang Junjie, Liu Xu, Pei Cuiying, Guo Jianggang, Ying Tianping
    • Year: 2025

  3. Intermediately Coupled Type-II Superconductivity in a La-Based Kagome Metal La₃Al

    • Authors: Yu Yingpeng, Liu Zhaolong, Chen Zhaoxu, Guo Jianggang, Jin Shifeng
    • Year: 2025
    • Citations: 1

  4. Dynamic-to-Static Switch of Hydrogen Bonds Induces a Metal–Insulator Transition in an Organic–Inorganic Superlattice

    • Authors: Xie Zhenkai, Luo Rui, Ying Tianping, Guo Jianggang, Chen Xiaolong
    • Year: 2024
    • Citations: 6

  5. Antiferromagnetic Frustration Behavior with Face-Sharing CuAs₄ Tetrahedrons in Conducting ACu₆As₃ (A = Li and Na)

    • Authors: Yang Yuxin, Chen Zhaoxu, Liu Xu, Chen Xu, Guo Jianggang
    • Year: 2024

  6. Evidence of a Hydrated Mineral Enriched in Water and Ammonium Molecules in the Chang’e-5 Lunar Sample

    • Authors: Jin Shifeng, Hao Munan, Guo Zhongnan, Guo Jianggang, Chen Xiaolong
    • Year: 2024
    • Citations: 6

  7. Quantum-Confined Tunable Ferromagnetism on the Surface of a Van der Waals Antiferromagnet NaCrTe₂

    • Authors: Li Yidian, Du Xian, Wang Junjie, Chen Yulin, Yang Lexian
    • Year: 2024

  8. Superconductivity in Pressurized Trilayer La₄Ni₃O₁₀−δ Single Crystals

    • Authors: Zhu Yinghao, Peng Di, Zhang Enkang, Guo Jianggang, Zhao Jun
    • Year: 2024
    • Citations: 41

  9. Influence of Dimensionality on Superconductivity in Pressurized 3D SnPSe₃ Single Crystal

    • Authors: Wang Junjie, Liu Xu, Zhang Ling, Guo Jianggang, Ying Tianping
    • Year: 2024

  10. High-Quality and Wafer-Scale Cubic Silicon Carbide Single Crystals

  • Authors: Wang Guobin, Sheng Da, Yang Yunfan, Guo Jianggang, Chen Xiaolong
  • Year: 2024
  • Citations: 10