Soft Matter group, Van der Waals-Zeeman Institute, IoP, Science Park 904, Amsterdam, The Netherlands.
Soft Matter. 2017 May 24;13(20):3734-3740. doi: 10.1039/c7sm00167c.
When subjected to shear, granular suspensions exhibit normal stresses perpendicular to the shear plane but the magnitude and sign of the different components of the normal stresses are still under debate. By performing both oscillatory and rotational rheology measurements on shear thickening granular suspensions and systematically varying the particle diameters and the gap sizes between two parallel-plates, we show that a transition from a positive to a negative normal stress can be observed. We find that frictional interactions which determine the shear thickening behavior of suspensions contribute to the positive normal stresses. Increasing the particle diameters or decreasing the gap sizes leads to a growing importance of hydrodynamic interactions, which results in negative normal stresses. We determine a relaxation time for the system, set by both the pore and the gap sizes, that governs the fluid flow through the inter-particle space. Finally, using a two-fluid model we determine the relative contributions from the particle phase and the liquid phase.
当颗粒悬浮液受到剪切时,会产生垂直于剪切面的法向应力,但不同法向应力分量的大小和符号仍存在争议。通过对剪切增稠颗粒悬浮液进行振荡和旋转流变学测量,并系统地改变平行板之间的粒径和间隙大小,我们观察到可以从正的法向应力转变为负的法向应力。我们发现,决定悬浮液剪切增稠行为的摩擦相互作用有助于产生正的法向应力。增加粒径或减小间隙大小会导致流体动力学相互作用变得更加重要,从而导致负的法向应力。我们确定了一个由孔径和间隙大小共同决定的系统弛豫时间,该时间控制着流体在颗粒间空间的流动。最后,使用双流体模型,我们确定了颗粒相和液相的相对贡献。