Microstructure Evolution and Properties of Gradient Nanostructures Subjected to Laser Shock Processing in 300M Ultrahigh‐Strength Steel

Herein, gradient nanostructures (GNs) are created in 300M ultrahigh‐strength (UHS) steel by laser shock processing (LSP). Microstructure evolution and properties of GNs subjected to LSP with different pulse energies are thoroughly characterized on 3D profiler, scanning electron microscope (SEM), tra...

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Bibliographic Details
Published in:Steel research international 2022-02, Vol.93 (2), p.n/a
Main Authors: Ma, Yun-fei, Xiong, Yi, Chen, Zheng-ge, Zha, Xiao-qin, He, Tian-tian, Li, Yong, Singh, Harishchandra, Kömi, Jukka, Huttula, Marko, Cao, Wei
Format: Article
Language:English
Subjects:
300M steel
Amorphization
Compressive properties
Dislocation density
Ductile fracture
Electron microscopes
Evolution
gradient nanostructures
Hardness
Heat treating
High strength steels
Laser shock processing
mechanical properties
Microstructure
microstructure evolution
Nanoindenters
Nanostructure
Nickel chromium molybdenum steels
Residual stress
Surface layers
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Summary:Herein, gradient nanostructures (GNs) are created in 300M ultrahigh‐strength (UHS) steel by laser shock processing (LSP). Microstructure evolution and properties of GNs subjected to LSP with different pulse energies are thoroughly characterized on 3D profiler, scanning electron microscope (SEM), transmission electron microscope (TEM), X‐ray diffractometer (XRD), X‐ray stress analyzer, nanoindenter, and tensile tester. Results show successful creations of GNs in 300M steel after LSP treatments. With the increase in pulse energy, the size of the surface layer is refined from 15 nm (3 J) to 10 nm (7 J), and the corresponding grains are amorphized to some extent. Meanwhile, many substructure defects such as dislocation tangles and deformation twins (DTs) are noted in the subsurface. The dislocation density and the number of DTs increase with the pulse energy. Further, the high compressive residual stress is introduced to the 300M steel surface after LSP, and the corresponding hardness is improved substantially. The compressive residual stress, depth of the affected layer, and the hardness rise significantly with the pulse energy. Apart from improvements in strength and plasticity, the fracture morphology is changed from a typical ductile fracture to quasicleavage and ductile mixed fracture. Herein, the gradient nanostructures are introduced on the 300M steel by laser shock processing. The surface grains are remarkably refined to the nanoscale. With the increase of laser pulse energy, the degree of the grain refinement and the depth of severe plastic deformation layer increase, and the corresponding strength and plasticity are also improved.
ISSN:1611-3683
1869-344X
DOI:10.1002/srin.202100434