Sen Lin scite author profile

Sen Lin

5Publications

46Citation Statements Received

82Citation Statements Given

How they've been cited

120

How they cite others

115

Affiliations

KTH Royal Institute of Technology, Tohoku University, Shanghai Jiao Tong University

Publications

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Micromechanics and microstructure evolution during in situ uniaxial tensile loading of TRIP-assisted duplex stainless steels

Tian

Lin

et al. 2018

Materials Science and Engineering: A

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Two transformation-induced plasticity (TRIP) assisted duplex stainless steels, with three different stabilities of the austenite phase, were investigated by synchrotron X-ray diffraction characterization during in situ uniaxial tensile loading. The micromechanics and the deformation-induced martensitic transformation (DIMT) in the bulk of the steels were investigated in situ. Furthermore, scanning electron microscopy supplemented the in situ analysis by providing information about the microstructure of annealed and deformed specimens. The dependence of deformation structure on austenite stability is similar to that of single-phase austenitic steels where shear bands and bcc-martensite (α') are generally observed, and blocky α' is only frequent when the austenite stability is low. These microstructural features, i.e. defect structure and deformation-induced martensite, are correlated with the micro-and macro-mechanics of the steels with elastoplastic load transfer from the weaker phases to the stronger α', in particular this occurs close to the point of maximum rate of α' formation. A clear strain-hardening effect from α' is seen in the most unstable austenite leading to a pronounced TRIP effect.

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Comparison of energy release rate and energy density criteria for a piezoelectric layered composite with a crack normal to interface

Lin

Narita

Shindo

2003

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Electroelastic analysis of a piezoelectric cylindrical fiber with a penny-shaped crack embedded in a matrix

Lin

Narita

Shindo

2003

International Journal of Solids and Structures

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Study on preparation and mechanical properties of bionic carbon fiber reinforced epoxy resin composite with eagle feather structure

Liang

Tuo

Zhao

et al. 2021

Mater. Res. Express

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Inspired by the effect of angle between feather shaft and the feather vane on strength enhancement of feather structure, carbon fiber reinforced epoxy resin composites with eagle feather structure were prepared successfully. Based on liquid-phase oxidation, wettability of carbon fiber was improved, which enhanced bonding strength between reinforcement and matrix and built material base for mechanical strength of bionic composite. With the increase of carbon fiber content (0.1 wt.%, 0.2 wt.%, 0.3 wt.% and 0.4 wt.%), tensile strength and impact toughness of carbon fiber reinforced epoxy resin composites increased first and then decreased. Composites with 0.2 wt.% carbon fiber exhibited optimal mechanical properties, which was used for preparation of bionic composite. Compared with carbon fiber reinforced epoxy resin composite with the traditional vertically arranged structure, the composite material with the bionic structure owned higher tensile strength and impact toughness. The fracture and drawing out of carbon fiber and crack deflection were mechanical mechanism of bionic composite, which provided a new design and preparation method for carbon fiber reinforced epoxy resin composite.

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Electroelastic analysis of a penny-shaped crack in a piezoelectric ceramic under mode I loading

Lin

Narita

Shindo

2003

Mechanics Research Communications

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Sen Lin

Micromechanics and microstructure evolution during in situ uniaxial tensile loading of TRIP-assisted duplex stainless steels

Comparison of energy release rate and energy density criteria for a piezoelectric layered composite with a crack normal to interface

Electroelastic analysis of a piezoelectric cylindrical fiber with a penny-shaped crack embedded in a matrix

Study on preparation and mechanical properties of bionic carbon fiber reinforced epoxy resin composite with eagle feather structure

Electroelastic analysis of a penny-shaped crack in a piezoelectric ceramic under mode I loading

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