Xiankun Zhang | materials science | Best Researcher Award

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Prof. Xiankun Zhang | materials science | Best Researcher Award

professor at  University of Science and Technology Beijing, China

📜 Xiankun Zhang is a leading researcher at the University of Science and Technology Beijing, specializing in two-dimensional materials, optoelectronic devices, and transition metal dichalcogenides. With over 44 publications and a high h-index of 22, Zhang has made significant contributions to advanced functional materials and nanoscale photodetectors. Passionate about integrating innovation into silicon-compatible technology, Zhang is a key figure in the field of material science.

Professional Profiles:

scopus

scholar

Education🎓

PhD in Material Science, University of Science and Technology Beijing, China Master’s Degree in Physics, Tsinghua University, China Bachelor’s Degree in Applied Physics, Peking University, China Focused on emerging materials and their optoelectronic applications, Zhang’s academic journey reflects a strong foundation in interdisciplinary research.

Experience💼 

Senior Researcher, University of Science and Technology Beijing Visiting Scholar, MIT Nano Research Lab Research Fellow, National Center for Nanoscience and Technology Zhang has actively collaborated with global leaders in the nanotechnology domain, showcasing excellence in research and innovation.

Awards and Honors🏅

National Science Fund for Distinguished Young Scholars Outstanding Researcher in Nanotechnology, China Materials Congress Highly Cited Researcher Award, Clarivate Analytics Recognized for transformative work in nanoscale photodetectors and 2D materials.

Research Focus🔬

Two-dimensional materials and heterojunctionsHigh-efficiency photodetectorsTransition metal dichalcogenidesSilicon-compatible optoelectronics Zhang’s work focuses on bridging the gap between traditional materials and next-generation electronic devices.

✍️Publications Top Note :

“Poly (4-styrenesulfonate)-induced sulfur vacancy self-healing strategy for monolayer MoS2 homojunction photodiode”
Published in Nature Communications, this paper has been cited 234 times, emphasizing a groundbreaking sulfur vacancy healing strategy for improved photodiodes.

“Manganese-Based Materials for Rechargeable Batteries Beyond Lithium-Ion”
Published in Advanced Energy Materials, this work, cited 153 times, advances manganese-based materials for next-generation batteries.

“Near-Ideal van der Waals Rectifiers Based on All-Two-Dimensional Schottky Junctions”
Another Nature Communications article, cited 153 times, discusses advancements in two-dimensional rectifiers.

“Interfacial Charge Behavior Modulation in Perovskite Quantum Dot-Monolayer MoS2 Heterostructures”
With 148 citations, this Advanced Functional Materials paper explores charge behavior in hybrid heterostructures.

“Defect-Engineered Atomically Thin MoS2 Homogeneous Electronics for Logic Inverters”
Published in Advanced Materials, cited 134 times, highlighting defect engineering in MoS2 for logic applications.

“Strain-Engineered van der Waals Interfaces of Mixed-Dimensional Heterostructure Arrays”
An ACS Nano publication with 116 citations, focusing on heterostructure arrays for enhanced device performance.

“Integrated High-Performance Infrared Phototransistor Arrays Composed of Nonlayered PbS–MoS2 Heterostructures”
Featured in Nano Letters, this study has 113 citations, addressing high-performance infrared photodetection.

“Hidden Vacancy Benefit in Monolayer 2D Semiconductors”
Advanced Materials work with 86 citations, detailing vacancy benefits in 2D semiconductors.

“Piezotronic Effect on Interfacial Charge Modulation in Mixed-Dimensional van der Waals Heterostructures”
Cited 82 times in Nano Energy, examining the piezotronic effect for flexible photodetectors.

“Self-Healing Originated van der Waals Homojunctions with Strong Interlayer Coupling for High-Performance Photodiodes”
Published in ACS Nano, cited 80 times, discussing self-healing junctions.

Conclusion

Xiankun Zhang’s prolific research output, significant citations, and impactful work in advanced materials science make him a strong candidate for the Best Researcher Award. Addressing areas such as broader dissemination, interdisciplinary applications, and community engagement could further solidify his standing as a leader in his field. His research aligns well with the award’s goals of recognizing innovation, collaboration, and impact in academia.