Cross-stream migration of a Brownian droplet in a polymer solution under Poiseuille flow

Howard, Michael P.; Truskett, Thomas M.; Nikoubashman, Arash

doi:10.1039/c8sm02552e

Cited by 6 publications

(11 citation statements)

References 92 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This phenomenon implies that the migration behavior toward the tube center is a common feature of star polymers, regardless of their functionality. This inward migration is also observed for the deformable soft particles (i.e., droplet, vesicles) in certain conditions. − In the regime of Re > 1, the soft particles migrate toward the centerline when the viscosity ratio between the suspended particles and the surrounding fluid varies from unity to 13 . Such inward migration is enhanced by increasing the particle deformability …”

Section: Results and Discussionmentioning

confidence: 65%

Role of Functionality in Cross-Stream Migration, Structures, and Dynamics of Star Polymers in Poiseuille Flow

et al. 2020

View full text Add to dashboard Cite

The effect of functionality on the migration behaviors, structural, and dynamical properties of star polymers in Poiseuille flow are investigated by multiparticle collision dynamics integrated with molecular dynamics simulations. Our studies reveal that the star polymer migrates toward the centerline of the cylindrical tube by increasing the flow strength and the degree of inward migration is amplified as the functionality or the number of monomers increases. At high flow strengths, the star polymer with low functionality undergoes a large conformational change due to the tumbling motion, and the tumbling motion is suppressed with increasing functionality, whereas the star polymer with high functionality maintains a steady, stretched state via a trumpet shape. We attribute this phenomenon to the fact that the star polymer with high functionality perturbs the surrounding solvents more strongly at high flow strengths than that with lower functionality, leading to the higher additional hydrodynamic drag forces. These forces are balanced by certain forces in each direction and stabilize the high-functionality star polymer near the centerline due to its trumpet-shaped configuration. Hence, the trumpet structure of star polymers amplifies the inward migration of polymer chains in Poiseuille flow.

show abstract

Section: Results and Discussionmentioning

confidence: 65%

Role of Functionality in Cross-Stream Migration, Structures, and Dynamics of Star Polymers in Poiseuille Flow

et al. 2020

View full text Add to dashboard Cite

show abstract

“…[ 12 ] Polymer solutions usually exhibit a Poiseuille flow in microchannels, and the velocity in the flow field is affected or determined by polymer chains. [ 13 ] In DPD, the finitely extensible nonlinear elastic (FENE) model is typically used to represent polymer chains. External forces and periodic boundary conditions [ 14–17 ] are applied at the inlet and outlet to drive polymer solution flow in the microchannel.…”

Section: Application Of Dpd On Mesoscale Properties Of Polymermentioning

confidence: 99%

Dissipative Particle Dynamics Simulation: A Review on Investigating Mesoscale Properties of Polymer Systems

Wang

Han

et al. 2021

Macro Materials & Eng

View full text Add to dashboard Cite

Polymer systems have typical multiscale characteristics, both in space and time. The mesoscopic properties of polymers are difficult to describe through traditional experimental approaches. Dissipative particle dynamics (DPD) is a simulation method used for solving mesoscale problems of complex fluids and soft matter. The mesoscopic properties of polymer systems, such as conformation, dynamics, and transport properties, have been studied extensively using DPD. This paper briefly summarizes the application of DPD to research involving microchannel flow, electrospinning, free‐radical polymerization, polymer self‐assembly processes, polymer electrolyte fuel cells, and biomedical materials. The main features and possible development avenues of DPD are described as well.

show abstract

“…The signac framework has been cited 54 times, according to Google Scholar, and has been used in a range of scientific fields with various types of computational workflows. Some of these studies include quantum calculations of small molecules [GG18], 4,480 simulations of epoxy curing (each containing millions of particles) [TAH + 18], inverse design of pair potentials [AADG18], identifying photonic band gaps in 151,593 crystal structures [CADG21], benchmarking atom-density representations for use in machine learning [MVG + 21], simulating fluid flow in polymer solutions [PHMTN19], design of optical metamaterials [HCVM20], and economic analysis of drought [Stu]. Much of the published research using signac comes from chemical engineering, materials science, or physics, the fields of many of signac's core developers and thus fields where the project has had greatest exposure.…”

Section: Applications Of Signacmentioning

confidence: 99%

signac: Data Management and Workflows for Computational Researchers

Dice¹,

Butler²,

Ramasubramani³

et al. 2021

Proceedings of the Python in Science Conference

View full text Add to dashboard Cite

The signac data management framework (https://signac.io) helps researchers execute reproducible computational studies, scales workflows from laptops to supercomputers, and emphasizes portability and fast prototyping. With signac, users can track, search, and archive data and metadata for filebased workflows and automate workflow submission on high performance computing (HPC) clusters. We will discuss recent improvements to the software's feature set, scalability, scientific applications, usability, and community. Newly implemented synced data structures, features for generalized workflow execution, and performance optimizations will be covered, as well as recent research using the framework and changes to the project's outreach and governance as a response to its growth.

show abstract

Cross-stream migration of a Brownian droplet in a polymer solution under Poiseuille flow

Cited by 6 publications

References 92 publications

Role of Functionality in Cross-Stream Migration, Structures, and Dynamics of Star Polymers in Poiseuille Flow

Role of Functionality in Cross-Stream Migration, Structures, and Dynamics of Star Polymers in Poiseuille Flow

Dissipative Particle Dynamics Simulation: A Review on Investigating Mesoscale Properties of Polymer Systems

signac: Data Management and Workflows for Computational Researchers

Contact Info

Product

Resources

About