Boundary shape, particularly roughness, strongly controls the amount of wall slip in dense granular flows. We aim to quantify and understand which aspects of a dense granular flow are controlled by the boundary conditions and to incorporate these observations into a cooperative nonlocal model characterizing slow granular flows. To examine the influence of boundary properties, we perform experiments on a quasi-2D annular shear cell with a rotating inner wall and a fixed outer wall; the latter is selected among 6 walls with various roughnesses, local concavity, and compliance. Measuring flow field and stress field throughout the material in experimental studies of granular materials is an ongoing challenge due to the complex nature of these materials. Here, we use innovative techniques to quantify stress field and flow field when different boundaries were used. We find that we can successfully capture the full flow profile using a single set of empirically determined model parameters, with only the wall slip velocity set by direct observation. Through the use of photoelastic particles, we observe how the internal stresses fluctuate more for rougher boundaries, corresponding to a lower wall slip, and connect this observation to the propagation of nonlocal effects originating from the wall. Our measurements indicate a universal relationship between dimensionless fluidity and velocity.

These data were collected of quasi-2D annular shear cells where particles are flowing in a quasi-static regime. With a camera above the apparatus, particle's motions were captured along with their interactions using an innovative technique (photoelasticity). Particles are disks made of photoelastic materials, and they are fllowing on a flat surface by a drived shearing wall. Velocity profile and shear rate profile are measured by tracking the particles. Shear stress profile and pressure profile are measured using photoelastic technique. 

They can be opened by Matlab. They are in the format of *.mat