Xinyang Normal University | China
Scopus Profile
Education
Prof. Dr. Haibin Sun laid a strong academic foundation in physics and material sciences. He earned his B.S. in Physics and Electronic Engineering from Xinyang Normal University, China, in 2003, followed by an M.S. in Physical Engineering from Zhengzhou University in 2006. He then pursued advanced studies and obtained his Ph.D. in Condensed Matter Physics from the National Laboratory of Solid State Microstructures and the College of Physics, Nanjing University, in 2015, under the supervision of Prof. Dr. Jianguo Wan and Prof. Guanghou Wang.
Experience
From 2006 to 2011, Prof. Dr. Haibin Sun served as a Lecturer in the College of Physics and Electronic Engineering at Xinyang Normal University. After completing his Ph.D., he advanced his academic career with significant research output in the field of low-dimensional materials, particularly graphene and nanostructured hybrids. His experience bridges both teaching and advanced experimental research, positioning him as a leading scholar in condensed matter physics.
Research Interest
His primary research interests focus on the Preparation and Magnetic Properties Research of Low-Dimensional Materials. He has worked extensively on the synthesis and characterization of graphene and its hybrids with nanoparticles. His groundbreaking studies include surface-enhanced Raman scattering in graphene-silver hybrids, scalable synthesis of monolayer and bilayer graphene using solid coronene by CVD, and cooling growth of millimeter-size single-crystal bilayer graphene. These works highlight his contributions to advancing graphene growth methods and understanding structural, optical, and magnetic properties of low-dimensional systems.
Awards and Honors
Prof. Sun’s pioneering contributions in Preparation and Magnetic Properties Research of Low-Dimensional Materials have earned him recognition in high-impact journals such as Applied Physics Letters, Carbon, and The Journal of Physical Chemistry C. His innovative approaches to graphene synthesis and his studies on surface-enhanced Raman scattering have been widely cited and acknowledged by the international scientific community. These achievements demonstrate his ability to address fundamental challenges in material preparation and applications.
Research Skills
Prof. Dr. Haibin Sun possesses strong research skills in chemical vapor deposition (CVD) techniques, Raman spectroscopy, transmission electron microscopy (TEM), and electrical/optical property characterization. His ability to develop novel methods for the growth of high-quality monolayer and bilayer graphene reflects his expertise in Preparation and Magnetic Properties Research of Low-Dimensional Materials. Furthermore, his interdisciplinary approach integrates physics, chemistry, and nanotechnology, making his work valuable for both academic and industrial applications.
Publication Top Notes
Title: Fe₃N/Fe₃O₄ hetero-nanocrystals embedded in porous carbon fibers for enhanced lithium storage
Journal: Dalton Transactions
Year: 2024
Title: Encapsulating Ultrafine In₂O₃ Particles in Carbon Nanofiber Framework as Superior Electrode for Lithium-Ion Batteries
Journal: Inorganics
Year: 2024
Citations: 1
Title: Construction of an n-Type Fluorinated ZnO Interfacial Phase for a Stable Anode of Aqueous Zinc-Ion Batteries
Journal: ACS Applied Materials & Interfaces
Year: 2024
Citations: 8
Title: Cobalt vacancy boosting Co₃₋ₓO₄@C with superior pseudocapacitive lithium storage
Journal: Journal of Power Sources
Year: 2024
Citations: 3
Title: Ru-Doped Ni₃Se₄/NiSe/Nitrogen-Doped Carbon Nanotube Heterostructure for Lithium Storage
Journal: ACS Applied Nano Materials
Year: 2024
Citations: 5
Title: Ultrafine CoRu alloy nanoclusters densely anchored on nitrogen-doped graphene nanotubes for a highly efficient hydrogen evolution reaction
Journal: Journal of Colloid and Interface Science
Year: 2024
Citations: 12
Conclusion
Prof. Dr. Haibin Sun has established himself as a distinguished researcher in the area of condensed matter physics, with a particular focus on Preparation and Magnetic Properties Research of Low-Dimensional Materials. His work on graphene growth, hybrid nanostructures, and surface-enhanced Raman scattering has provided new insights into the design and application of advanced materials. Looking forward, his contributions are expected to further impact fields such as electronics, photonics, and energy storage, consolidating his role as a leader in low-dimensional materials research.