Team Introduction

Zhenjia Xie    associate researcher

Zhenjia Xie, born on February, 1987, associate professor in Collaborative Innovation Center of Steel. In 2010, he graduated from Beijing University of Science and Technology with a major in materials physics. In 2016, he received his Ph.D. in materials ph

Zhenjia Xie, born on February, 1987, associate professor in Collaborative Innovation Center of Steel. In 2010, he graduated from Beijing University of Science and Technology with a major in materials physics. In 2016, he received his Ph.D. in materials physics from Beijing University of Science and Technology. His research interests are in phase transformation and microstructure control in steel, microstructure characterization, structure-property correlation and thermodynamics simulation.

【Research Projects】

1. National Natural Science Foundation of China, Retained austenite stabilization and toughening mechanism in low alloy steels, （51701012），2017-2021

【Publications】

1. Xie ZJ, Han G, Zhou WH, Wang XL, Shang CJ, Misra RDK, A novel multi-step intercritical heat treatment induces multi-phase microstructure with ultra-low yield ratio and high ductility in advanced high-strength steel, Scripta Materialia, 2018, 155: 164-168.

2. Xie ZJ, Shang CJ, Subramanian SV, Ma XP, Misra RDK, Atom probe tomography and numerical study of austenite stabilization in a low carbon low alloy steel processed by two-step intercritical heat treatment, Scripta Materialia, 2017, 137: 36-40.

3. Xie ZJ, Shang CJ, Wang XL, Ma XP, Subramanian SV, Misra RDK, Microstructure-property relationship in a low carbon Nb-B bearing ultra-high strength steel by direct-quenching and tempering, Materials Science and Engineering: A, 2018, 727: 200-207.

4. Xie ZJ, Ma XP, Shang CJ, Wang XM, Subramanian SV, Nano-sized precipitation and properties of a low carbon niobium micro-alloyed bainitic steel, Materials Science and Engineering: A, 2015, 641: 37-44.

5. Xie ZJ, Fang YP, Han G, Guo H, Misra RDK, Shang CJ, Structure–property relationship in a 960 MPa grade ultrahigh strength low carbon niobium–vanadium microalloyed steel: The significance of high frequency induction tempering, Materials Science and Engineering: A, 2014, 618: 112-117.