Jin Tao Lu scite author profile

A conceptual study on damage wave propagation in elastic-brittle materials is carried out within the framework of Continuum Damage Mechanics (CDM). The extent of damage at a material point is a direct result of the evolution of microstructures and interaction with their neighbors. To account for the spatial fluctuation of damage, its gradient is proposed as an additional internal variable. The microstructural interaction can induce irreversible energy in the construction of the thermodynamic functions, through a range of dissipative mechanisms associated with microstructural changes such as nucleation, growth, and coalescence of microcracks, internal friction, irreversible phase transformation, and chemical reactions in elastic-brittle materials. Based on the theory of internal variables, a new material constitutive model involving damage evolution is presented. The governing equations for the corresponding coupled mechanism are derived and a traveling-wave solution is obtained for some limiting cases. It is shown that the evolution equation of damage is a nonlinear wave equation that has a solitary wave solution of the kink type in one-dimensional case if there is no energy dissipation with damage evolution. The speed of damage waves is determined in terms of the damping effect, the elastic energy of un-deformed material, and the dissipative energy. It is lower than the speed of elastic waves, and has a speed limit only associated with damage evolution at microscales. It is demonstrated that the theory presented here shows promise in describing damage wave propagation based upon comparisons with the available experimental results and numerical simulations.

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Room‐Temperature Mechanical Properties of V₂₀Nb₂₀Mo₂₀Ta₂₀W₂₀ High‐Entropy Alloy

Wang

et al. 2018

Adv Eng Mater

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Refractory high‐entropy alloys (HEAs) have shown promising high temperature strengths, while their mechanical behaviors at room temperature are rarely reported. In this work, the room‐temperature mechanical properties of V20Nb20Mo20Ta20W20 refractory HEA under various different loading modes including tension, compression, bending, shear loading, and microhardness are investigated. The results show that this alloy exhibits very high compressive strength but quite low strengths under tension, bending, and shear loading, similar to the conventional brittle materials. However, pronounced plasticity and slip bands are observed in compression samples, and no indentation cracking is observed in low‐load microhardness tests, which indicate the potential ability of plastic deformation in this refractory HEA. The present work suggests that the microstructure or composition of this HEA should be carefully tailored before its practical usage to suppress its large tendency for cracking and eventually improve its ductility and strength under tension.

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Predicting long-term creep-rupture property of Inconel 740 and 740H

Dang

Zhao

Yuan

et al. 2016

Materials at High Temperatures

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Oxidation behavior of a new Fe–Ni–Cr-based alloy in pure steam at 750 °C

Yang

Yuan

et al. 2016

Materials at High Temperatures

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Jin Tao Lu

A Modified HR3C Austenitic Heat-Resistant Steel for Ultra-supercritical Power Plants Applications Beyond 650 °C

A Preliminary Study on Damage Wave in Elastic-brittle Materials

Room‐Temperature Mechanical Properties of V₂₀Nb₂₀Mo₂₀Ta₂₀W₂₀ High‐Entropy Alloy

Predicting long-term creep-rupture property of Inconel 740 and 740H

Oxidation behavior of a new Fe–Ni–Cr-based alloy in pure steam at 750 °C

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Jin Tao Lu

A Modified HR3C Austenitic Heat-Resistant Steel for Ultra-supercritical Power Plants Applications Beyond 650 °C

A Preliminary Study on Damage Wave in Elastic-brittle Materials

Room‐Temperature Mechanical Properties of V20Nb20Mo20Ta20W20 High‐Entropy Alloy

Predicting long-term creep-rupture property of Inconel 740 and 740H

Oxidation behavior of a new Fe–Ni–Cr-based alloy in pure steam at 750 °C

Contact Info

Product

Resources

About

Room‐Temperature Mechanical Properties of V₂₀Nb₂₀Mo₂₀Ta₂₀W₂₀ High‐Entropy Alloy