Mr. zhixuan wang | Laser Welding | Best Researcher Award

Student at Xi’an University of Architecture and Technology, China

Zhixuan Wang, hailing from China, is a driven student at Xi’an University of Architecture and Technology. His passion for exploring the intricacies of laser welding led him to delve into the mechanisms of crack formation and propagation in Mo-14Re alloy laser-welded joints. Through meticulous experimentation and analysis using advanced techniques such as optical microscopy and scanning electron microscopy, Zhixuan uncovered critical insights into the underlying factors contributing to welding defects.

Professional Profiles:

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Education

phd, Xi ‘an University of Architecture and Technology, Wenyi Road, Beilin District, Xi ‘an, Shaanxi, China

Achievements

His groundbreaking research not only sheds light on the complexities of laser welding but also offers practical solutions for mitigating defects and enhancing the application value of refractory metal alloys. Zhixuan’s exemplary work has earned him the prestigious Best Researcher Award, solidifying his position as a trailblazer in the field of materials science and engineering.

Research Interest

Laser Welding Optimization, Defect Suppression, Microstructural Analysis, Materials Engineering, Process Optimization for Aerospace Applications.

Research Focus:

Zhixuan Wang’s research focus lies in the field of power electronics and wireless power transfer systems. He specializes in the development and optimization of control strategies for various applications, including maximum power point tracking in omnidirectional wireless power transfer systems. Zhixuan has contributed significantly to research articles published in prestigious journals such as IEEE Transactions on Industrial Electronics and the Journal of Power Electronics. His expertise encompasses areas such as resonant driving schemes, matching network design, and modulation strategies for minimizing power losses in DC-DC converters. Zhixuan’s work demonstrates a commitment to advancing efficient and reliable power transfer technologies for diverse industrial and consumer applications.

Publications

1. Variable frequency triple-phase-shift modulation strategy for minimizing RMS current in dual-active-bridge DC-DC converters, cited by: 6, Publication: 2021.
2. Research on Maximum Power Point Tracking Control in Omnidirectional Wireless Power Transfer System, Publication: 2023.
3. Resonant driving scheme for p-doped gallium nitride high electron mobility transistor to reduce driving power loss, Publication: 2023.
4. Matching network design for input impedance optimization of four-coil magnetic resonance coupling wireless power transfer systems, cited by: 3, Publication: 2022.
5. Correction to: Variable frequency triple‑phase‑shift modulation strategy for minimizing RMS current in dual‑active‑bridge DC‑DC converters,Publication: 2021.