Fawei Tang

Title: Fawei Tang: Innovator in Mechanical Behavior Simulation of Composite Materials

Introduction

Fawei Tang is a prominent inventor based in Beijing, China. He has made significant contributions to the field of computational material science, particularly in simulating the mechanical behaviors of multiphase composite materials. His innovative approach combines various scales of analysis to enhance the understanding of material properties.

Latest Patents

Fawei Tang holds a patent for a "Multi-scale method for simulating mechanical behaviors of multiphase composite materials." This patent describes a computer simulation analysis method that is suitable for depicting the mechanical behavior of multiphase composites based on their real microstructure. The method integrates first-principles calculations at the nanoscale, molecular dynamics simulations at the microscale, and thermodynamic calculations at the mesoscale. This comprehensive approach allows for the extraction of essential physical parameters required for finite element simulations at the macroscale, including elastic and plastic properties of each phase in the composite under varying temperatures and grain sizes.

Career Highlights

Fawei Tang is affiliated with the Beijing University of Technology, where he applies his expertise in computational material science. His work has been instrumental in advancing the understanding of multiphase composites and their mechanical behaviors. Through his research, he has developed methods that utilize focused ion beam experiments and image processing to obtain real material microstructures.

Collaborations

Fawei Tang has collaborated with notable colleagues, including Xiaoyan Song and Hao Lu. Their joint efforts have contributed to the advancement of research in the field of material science.

Conclusion

Fawei Tang's innovative work in simulating the mechanical behaviors of multiphase composite materials has made a significant impact in the field of computational material science. His contributions continue to enhance the understanding of material properties and behaviors under various conditions.