Unexpected viscoelastic deformation of tight sandstone: Insights and predictions from the fractional Maxwell model

Ding, Xiang; Zhang, Guangqing; Zhao, Bo; Wang, Yan

doi:10.1038/s41598-017-11618-x

Cited by 33 publications

(26 citation statements)

References 58 publications

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“…52,53 This led to the development of a new formalism for the modelling of viscoelastic materials known as fractional viscoelasticity. Fractional viscoelasticity has been applied to complex geological and construction materials such as bitumen (asphalt), 44,45 concrete, 42,43 rock mass, [54][55][56][57][58][59] waxy crude oil, 60,61 as well as polymers and gels, 41,[62][63][64][65] and food. 11 Numerous examples can also be found of fractional viscoelasticity applied to biological materials such as epithelial cells, 66 breast tissue cells, 67,68 lung parenchyma, 69 blood flow, 70,71 as well as red blood cell membranes.…”

Section: Introductionmentioning

confidence: 99%

Fractional viscoelastic models for power-law materials

et al. 2020

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Section: Introductionmentioning

confidence: 99%

Fractional viscoelastic models for power-law materials

et al. 2020

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“…It consists of two springs and two dashpots where a pair of spring and dashpot connected in parallel can be considered as a Kelvin submodel. In other words, the Burgers model is composed of three components including a spring, a dashpot, and a Kelvin submodel connected in series …”

Section: Analysis Model For the Surface Shape Development Of The Pitcmentioning

confidence: 99%

Surface shape development of the pitch lap under the loading of the conditioner in continuous polishing process

et al. 2018

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Continuous polishing using the pitch lap is a key process in finishing large flat optical elements. The optical elements’ surface figure is primarily dependent on the surface shape of the pitch lap, which is controlled by a large‐size conditioner. However, underlying fundamentals of the process control is not yet clear, and it remains empirical and nondeterministic to date. In this study, a novel analysis model is proposed for exploring the surface shape development of the pitch lap under the conditioner loading. The analysis model divides the polishing time into a series of segments, in which the shape variation of the pitch lap due to viscoelastic creep is derived from the pressure distribution at the conditioner‐lap contact interface. Further, a contact model of the lap and conditioner is built to obtain the pressure distribution at the interface, and a novel creep model is proposed for the viscoelastic behavior of the pitch lap under the pressure. The analysis model combined with the contact and viscoelastic models can be used to explore the pitch lap shape development under various conditions and hence reveal the underlying fundamentals of controlling the lap shape by the conditioner.

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“…erefore, the original Maxwell model requires improvements. In recent years, some scholars [27][28][29][30][31][32] have applied fractional calculus to improve the original Maxwell model. ese improved Maxwell models can approximately describe the partial nonlinear creep deformation of geotechnical materials.…”

Section: Introductionmentioning

confidence: 99%

New Maxwell Creep Model Based on Fractional and Elastic‐Plastic Elements

Tang

Wang

Duan

2020

Advances in Civil Engineering

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Creep models are mainly used to describe the rheological behaviour of geotechnical materials. An important research focus for studying creep in geotechnical materials is the development of a model with few parameters and good simulation performance. Hence, in this study, by replacing the Newtonian dashpot and spring in the classical Maxwell model with fractional and elasticplastic elements, a new Maxwell creep model based on fractional derivatives and continuum damage mechanics was developed. One-and three-dimensional (1D/3D) creep equations of the new Maxwell creep model were derived. e 1D creep equation of the new model was used to fit existing creep data of rock salt, and the 3D creep equation was used to fit the creep data of remolded loess. e model curves matched the creep data very well, showing considerably higher accuracy than other models. Furthermore, a sensitivity study was carried out, showing the effects of the fractional derivative order β and exponent α on the creep strain of rock salt.is new model is simple with few parameters and can effectively simulate the complete creep behaviour of geotechnical materials.

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Unexpected viscoelastic deformation of tight sandstone: Insights and predictions from the fractional Maxwell model

Cited by 33 publications

References 58 publications

Fractional viscoelastic models for power-law materials

Fractional viscoelastic models for power-law materials

Surface shape development of the pitch lap under the loading of the conditioner in continuous polishing process

New Maxwell Creep Model Based on Fractional and Elastic‐Plastic Elements

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