Representative Academic Papers (Papers of the Chinese Academy of Sciences Region 2 and above)

[1] Wang P, Feng W, Zhang J, et. al. Structural optimization of single-strand crucible for planar flow casting: simulation and application study. Physics of Fluids, 2025, 37: 063318.

[2] Wang P, Liu J, Zhang J, et. al. Investigation on close-coupled gas atomization for Fe-based amorphous powder production via simulation and industrial trials: Part II. Particle flight and cooling during secondary atomization. Journal of Materials Research and Technology, 2023, 26: 9480.

[3] Wang P, Liu J, Zhang J, et. al. Breakup process modeling and production of FeSiAl magnetic powders by close-coupled gas atomization. Journal of Materials Research and Technology, 2023, 23: 730.

[4] Wang P, Zhu Z, Zhang J, et. al. Industrial-scale fabrication of FeSiBC cores with balanced soft magnetic properties by transverse magnetic field annealing and mixing of carbonyl iron powder. Journal of Alloys and Compounds, 2024, 977: 173381.

[5] Wang P, Zhu Z, Zhang J, et. al. Industrial-scale fabrication of FeSiCr magnetic powder cores with high magnetic permeability and low loss. Journal of Alloys and Compounds, 2023, 962: 171095.

[6] Wang P, Liu J, Zhang J, et. al. Industrial-scale fabrication of amorphous magnetic powder cores with excellent high-frequency magnetic properties: Optimization for kinds and content of insulating agents. Journal of Non-Crystalline Solids, 2023, 605: 122082.

[7] Wang P, Wei M, Zhang J, et. al. Crystallization evolution behavior of amorphous Fe85.7Si7.9B3.6Cr2C0.8 powder produced by a novel atomization process. Journal of Non-Crystalline Solids, 2022, 594: 121824.

[8] Wang P, Tang H, Zhang J, et. al. Improved In-Mold Metallurgical Behavior for Slab Casting of IF Steels by a Novel Multi-Poles Electromagnetic Stirring. Metallurgical and Materials Transactions B, 2022, 53: 1691.[9]     Wang P, Tang H, Zhang J, et. al. Influence of Dual-Channel Induction Heating Coil Parameters on the Magnetic Field and Macroscopic Transport Behavior in T-Type Tundish. Metallurgical and Materials Transactions B, 2021, 52(5): 3447.

[10] Wang P, Cheng L, Zhang J, et. al. Propagation form of internal cracks induced by continuous casting soft reduction and control strategy for internal quality. Journal of Iron and SteelResearch International, 2024, 31: 622.

[11] Wang P, Xiao H, Zhang J, et. al. Effect of channel diameter on magneto-thermal conversion ratio and consistency of each strand in a multi-strand induction heating tundish. Journal of Iron and Steel Research International, 2023, 30: 1199.

[12] Chen X, Wang P*, Zhang J. Evaluation of the Adaptability of the Dual-Port Channel in Induction Heating Tundish. Metallurgical and Materials Transactions B, 2025.

[13] Chen X, Wang P*, Xiao H, et. al. Dual optimization of the geometric design and inductor parameters of the induction heating tundish based on numerical simulations. Journal of Materials Research and Technology, 2023, 24: 1410.

[14] Chen X, Wang P*, Zhang J, et. al. New electromagnetic variable flow device for slab continuous casting mold: mechanical design and magnetic field analysis. Journal of Iron and Steel Research International, 2024, 31:2710-2726.

[15] Liu J, Li B, Wang P*, et al. Optimization of the gas system for gas–water combined atomization technique in FeSiBC amorphous powder production. Physics of Fluids, 2024, 36: 073317.

[16] Liu J, Wang P*, Zhang J, et al. Investigation on close-coupled gas atomization for Fe-based amorphous powder production via simulation and industrial trials: Part I. Melt breakup behaviors during primary atomization. Journal of Materials Research and Technology, 2023, 27: 6568.

[17] Liu J, Dong Y, Wang P*, et. al. Improved high-frequency magnetic properties of FeSiBCCr amorphous soft magnetic composites by adding carbonyl iron powders. Journal of Non-Crystalline Solids, 2023, 605:122166. （ESI高被引）

[18] Liu J, Wang P*, Zhang J, et al. FeSiBCCr bulk metallic glasses with excellent soft magnetic properties prepared using spark plasma sintering technology. Journal of Non-Crystalline Solids. 2024, 645: 123205.

[19] Liu J, Gao Y, Wang P*, et al. Structure evolution and magnetization properties of FeSiBCCr amorphous alloys prepared by spark plasma sintering. Journal of Non-Crystalline Solids, 2023, 622: 122651.

[20] Liu J, Zhu Z, Wang P*, et al. Effects of two silicone resin coatings on performance of FeSiAl magnetic powder cores. Journal of Iron and Steel Research International, 2024, 31(5): 1279.

[21] Liu J, Dong Y, Wang P*, et. al. Simulation and experiment study on the fabrication of Fe-based amorphous powders by a novel atomization process equipped with assisted gas nozzles. Journal of Iron and Steel Research International, 2023, 30(6): 1142.

[22] Zhu Z, Wang P*, Zhang J, et. al. Improving the magnetic properties of FeSiBC soft magnetic composites by flake powder orientation and mixing with FeSiBCCr fine powder. Journal of Materials Research and Technology, 2024, 33: 8519.

[23]   Geng H, Chang Y, Wang P*, et al. Insight into effect of forced convection during slab casting on as-cast solidification structure. Journal of Iron and Steel Research International, 2024: 1.

[24] Wang H, Zhang Z, Wang P*, et al. Soft reduction control investigation of spot segregation in continuous casting bloom for 42CrMoA crankshaft steel. Journal of Iron and Steel Research International, 2025, 32: 695.

[25] Wang H, Zhang Z, Wang P*, et al. Controlling segregation and hardenability of gear steel based on as-cast structure. Journal of Iron and Steel Research International, 2025, 32: 144.  

Authorized invention patents

[1] The first inventor, invention patent CN 116644688 B, a forward control method for atomization production based on the prediction of crushing mode.

[2] First inventor, invention patent CN 117030410 B, a method for preparing metallographic samples of ultra-thin metal materials.

[3] First inventor, invention patent CN 116904831 B, a Fe-Si-B based bulk amorphous alloy preparation method and material.

[4] The first inventor, invention patent CN 116992794 B, a method for calculating the yield rate of atomized amorphous powder and its application.

[5] The first inventor, invention patent CN 117174424 B, a high-performance alloy magnet for inductors and preparation method.

[6] The first inventor, invention patent CN 116738518 B, a numerical simulation verification method and internal quality control method for the position of cracks under light pressure in continuous casting.

[7] First inventor, invention patent CN 117226059 B, improved pressure control method for macro and semi-macroscopic segregation of high-carbon and low-alloy steel.

[8] First inventor, invention patent CN 117548638 B, method for improving ribbon defects and mechanical properties of rods and camshafts.

[9] First inventor, invention patent CN 115509266 B, a control device for rapid reaction to regulate melt flow, control method and application.

[10] First inventor, invention patent CN 116833399 B, a steel continuous casting induction heating tundish and its control method.

[11] The first inventor, invention patent CN 1198899 B, an iron-based amorphous composite magnetic powder core and preparation method.

[12] First inventor, invention patent CN 119864112 B, a thermoplastic prediction model, method, electronic device, or storage medium.

[13] First inventor, invention patent CN 119187485 B, a method for improving the hardenability of gear steel bars and gear steel bars.