Shaowen Xu scite author profile

A brief summary of recent finite element simulation results for the friction stir welding process is presented. The focus of the present study is on the characterisation of material flow around the rotating tool pin. Material flow patterns predicted by finite element simulations are found to compare favourably with experimental observations. The simulation results also reveal that material particles tend to pass and move behind the rotating pin from the trailing side, rather than both sides, of the pin. Possible variations in the material flow pattern due to variations in process parameters are discussed.

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A study of texture patterns in friction stir welds

Deng

2008

Acta Materialia

130

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Application of 3D image correlation for full-field transient plate deformation measurements during blast loading

Tiwari

Sutton

McNeill

et al. 2009

International Journal of Impact Engineering

148

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Flexural resonance mechanism of thermal transport across graphene-SiO2 interfaces

Ong

Qiu

et al. 2018

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Understanding the microscopic mechanism of heat dissipation at the dimensionally mismatched interface between a two-dimensional (2D) crystal and its substrate is crucial for the thermal management of devices based on 2D materials. Here, we study the lattice contribution to thermal (Kapitza) transport at graphene-SiO2 interfaces using molecular dynamics (MD) simulations and non-equilibrium Green's functions (NEGF). We find that 78 percent of the Kapitza conductance is due to sub-20 THz flexural acoustic modes, and that a resonance mechanism dominates the interfacial phonon transport. MD and NEGF estimate the classical Kapitza conductance to be hK ≈ 10 to 16 MW K−1 m−2 at 300 K, respectively, consistent with existing experimental observations. Taking into account quantum mechanical corrections, this value is approximately 28% lower at 300 K. Our calculations also suggest that hK scales as T2 at low temperatures (T < 100 K) due to the linear frequency dependence of phonon transmission across the graphene-SiO2 interface at low frequencies. Our study sheds light on the role of flexural acoustic phonons in heat dissipation from graphene to its substrate.

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Shaowen Xu

Finite element simulation of material flow in friction stir welding

A study of texture patterns in friction stir welds

Application of 3D image correlation for full-field transient plate deformation measurements during blast loading

Flexural resonance mechanism of thermal transport across graphene-SiO2 interfaces

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