有限时效粘弹性流体径向位移的模式选择

Q3 Materials Science JCIS open Pub Date : 2022-07-01 DOI:10.1016/j.jciso.2022.100047
Palak, Vaibhav Raj Singh Parmar, Debasish Saha, Ranjini Bandyopadhyay
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引用次数: 3

摘要

复杂的流体位移模式是由界面扰动的不稳定增长引起的,可以由流体粘弹性和表面张力驱动。由于悬浮体微观结构的自发形成,软玻璃状悬浮体老化,即其力学模量随时间而变化。在牛顿流体的作用下,老化悬浮液的剪切和随时间变化的流变特性可以产生各种各样的界面模式。利用视频成像技术,我们发现了丰富的界面模式形态:致密粘性、枝晶状、粘弹性断裂、花状、锯齿状和稳定的界面形态,这些界面形态存在于牛顿流体以不同的流速注入径向准二维几何结构的混溶和非混溶过程中。我们提出了一个新的参数,即面积比,我们将其定义为由包围它的最小圆的面积归一化的完全发育的图案面积。我们发现,面积比的自然对数唯一地识别了不同的模式形态,这样每个模式都可以在由悬浮时效时间、驱替流体流速和界面张力跨越的三维相图中分离出来。我们的结果除了具有根本性的意义外,还有助于预测和控制流体驱替过程中界面的增长。
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Pattern selection in radial displacements of a confined aging viscoelastic fluid

Intricate fluid displacement patterns, arising from the unstable growth of interfacial perturbations, can be driven by fluid viscoelasticity and surface tension. A soft glassy suspension ages, i.e. its mechanical moduli evolve with time, due to the spontaneous formation of suspension microstructures. The shear and time-dependent rheology of an aging suspension can be exploited to generate a wide variety of interfacial patterns during its displacement by a Newtonian fluid. Using video imaging, we report a rich array of interfacial pattern morphologies: dense viscous, dendritic, viscoelastic fracture, flower-shaped, jagged and stable, during the miscible and immiscible displacements of an aging colloidal clay suspension by Newtonian fluids injected into a radial quasi-two-dimensional geometry at different flow rates. We propose a new parameter, the areal ratio, which we define as the fully developed pattern area normalized by the area of the smallest circle enclosing it. We show that the natural logarithms of the areal ratios uniquely identify the distinct pattern morphologies, such that each pattern can be segregated in a three-dimensional phase diagram spanned by the suspension aging time, the displacing fluid flow rate, and interfacial tension. Besides being of fundamental interest, our results are useful in predicting and controlling the growth of interfaces during fluid displacements.

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来源期刊
JCIS open
JCIS open Physical and Theoretical Chemistry, Colloid and Surface Chemistry, Surfaces, Coatings and Films
CiteScore
4.10
自引率
0.00%
发文量
0
审稿时长
36 days
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