Browsing School of Engineering and Materials Science by Author "Xu, D"
Now showing items 1-12 of 12
-
A computational model of ureteral peristalsis and an investigation into ureteral reflux.
Hosseini, G; Ji, C; Xu, D; Rezaienia, MA; Avital, E; Munjiza, A; Williams, JJR; Green, JSA (2018-02)The aim of this study is to create a computational model of the human ureteral system that accurately replicates the peristaltic movement of the ureter for a variety of physiological and pathological functions. The objectives ... -
Effects of alirocumab on types of myocardial infarction: insights from the ODYSSEY OUTCOMES trial
White, HD; Steg, PG; Szarek, M; Bhatt, DL; Bittner, VA; Diaz, R; Edelberg, JM; Erglis, A; Goodman, SG; Hanotin, C (2019-09-01) -
Fluid-structure Interaction of Flexible Submerged Vegetation Stems and Kinetic Turbine Blades
Wang, M; Avital, E; Bai, X; Ji, C; Xu, D; Williams, JJR; Munjiza, A (Springer (part of Springer Nature), 2019-12-13)A fluid-structure interaction (FSI) methodology is presented for simulating elastic bodies embedded and/or encapsulating viscous incompressible fluid. The fluid solver is based on finite volume and the large eddy simulation ... -
Insights into in-situ catalytic degradation of plastic wastes over zeolite-based catalyst from perspective of three-dimensional pore structure evolution
Xu, D; Lu, X; Zhang, Y; Shearing, PR; Zhang, S; Brett, DJL; Wang, S (Elsevier, 2022-12-15)Insightfully understanding the process of volatiles from plastic depolymerization entering from the exterior into internal structure of catalyst favors to rationalize the catalyst design in scale-up principles. Herein, ... -
An Investigation on the Aggregation and Rheodynamics of Human Red Blood Cells Using High Performance Computations
Xu, D; Ji, C; Avital, E; Kaliviotis, E; Munjiza, A; Williams, J (2017) -
Large scale simulation of red blood cell aggregation in shear flows
Xu, D; Kaliviotis, E; Munjiza, A; Avital, E; Ji, C; Williams, J (2013-07-26) -
A Novel Contact Algorithm Based on a Distance Potential Function for the 3D Discrete-Element Method
Zhao, L; Liu, X; Mao, J; Xu, D; Munjiza, A; Avital, E (2018-12) -
A novel discrete element method based on the distance potential for arbitrary 2D convex elements
Zhao, L; Liu, X; Mao, J; Xu, D; Munjiza, A; Avital, E (2018-07-13) -
Saltation of particles in turbulent channel flow
Ji, C; Munjiza, A; Avital, E; Xu, D; Williams, J (American Physical Society, 2014-05-07)This paper numerically investigates particle saltation in a turbulent channel flow having a rough bed consisting of two to three layers of densely packed spheres. The Shields function is 0.065 which is just above the ... -
Saltation of particles in turbulent channel flow
Ji, C; Munjiza, A; Avital, E; Xu, D; Williams, J (2014-05-07) -
Saltation of particles in turbulent channel flow.
Ji, C; Munjiza, A; Avital, E; Xu, D; Williams, J (2014-05)This paper numerically investigates particle saltation in a turbulent channel flow having a rough bed consisting of two to three layers of densely packed spheres. The Shields function is 0.065 which is just above the ... -
Study on the packed volume-to-void ratio of idealized human red blood cells using a finite-discrete element method
Xu, D; Ji, C; Munjiza, A; Kaliviotis, E; Avital, E; Willams, J (Springer Nature, 2019)Numerical simulations are performed to examine the packing behavior of human red blood cells (RBCs). A combined finite-discrete element method (FDEM) is utilized, in which the RBCs are modeled as no-friction and no-adhesion ...