Hele-Shaw rheometry

Drost, S.; Westerweel, J.

doi:10.1122/1.4824856

Cited by 12 publications

(7 citation statements)

References 21 publications

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“…However, no asymmetry is observed for PEO, a result that extends to a range of flow rates and polymer concentrations. On further consideration [14], the absence of fore-aft asymmetry in this viscoelastic flow is not surprising: for the sheared flow in the narrow geometry of our Hele-Shaw cell, the extensional stresses are suppressed and the Weissenberg number is relatively small [typical shear rates are 0. scales comparable to the height of the slot (here H ∼ 1 mm, which is comparable in size to the discrepancy between theory and experiment) or by the complications in defining the edge of the plug due to undetectable velocities. Such possibilities cannot, however, rationalize the second difference between the Carbopol and earlier tests, which is that there is a marked fore-aft asymmetry in the flow pattern, with the plug at the front being larger than that at the rear, and mirrors findings for unconfined flows [7,8].…”

Section: A Plug Phenomenologymentioning

confidence: 89%

Obstructed viscoplastic flow in a Hele-Shaw cell

et al. 2020

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Experiments are conducted exploring the flow of Carbopol past obstacles in a narrow slot and compared with predictions of a model based on the Herschel-Bulkley constitutive law and the conventional Hele-Shaw approximation. Although Carbopol is often assumed to be a relatively simple yield-stress fluid, the flow pattern around an obstacle markedly lacks the fore-aft symmetry expected theoretically. Such asymmetry has been observed previously for viscoplastic flows past obstacles in unconfined geometries, but the narrowness of the Hele-Shaw cell ensures that the stress state is very different, placing further constraints on the underlying origin. The asymmetry is robust, as demonstrated by varying the shape and number of the obstacles, the surfaces of the cell walls, and the steadiness of the flow rate. The results suggest that rheological hysteresis near the yield point may be the cause of the asymmetry.

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Section: A Plug Phenomenologymentioning

confidence: 89%

Obstructed viscoplastic flow in a Hele-Shaw cell

et al. 2020

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“…In the past decade, microfluidics has been an integral part of rheometry techniques [116] and various microdevices have been developed to probe the mechanical properties of human blood plasma [117], circulating cells [118], Newtonian and non-Newtonian liquids [119], power-law fluids [120], etc. However, few microfluidic rheometers are specialized to measure the rheological characteristics of bacterial biofilms.…”

Section: Rheology Of Biofilmsmentioning

confidence: 99%

Interplay of physical mechanisms and biofilm processes: review of microfluidic methods

et al. 2015

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Bacteria in natural and artificial environments often reside in self-organized, integrated communities known as biofilms. Biofilms are highly structured entities consisting of bacterial cells embedded in a matrix of self-produced extracellular polymeric substances (EPS). The EPS matrix acts like a biological ‘glue’ enabling microbes to adhere to and colonize a wide range of surfaces. Once integrated into biofilms, bacterial cells can withstand various forms of stress such as antibiotics, hydrodynamic shear and other environmental challenges. Because of this, biofilms of pathogenic bacteria can be a significant health hazard often leading to recurrent infections. Biofilms can also lead to clogging and material degradation; on the other hand they are an integral part of various environmental processes such as carbon sequestration and nitrogen cycles. There are several determinants of biofilm morphology and dynamics, including the genotypic and phenotypic states of constituent cells and various environmental conditions. Here, we present an overview of the role of relevant physical processes in biofilm formation, including propulsion mechanisms, hydrodynamic effects, and transport of quorum sensing signals. We also provide a survey of microfluidic techniques utilized to unravel the associated physical mechanisms. Further, we discuss the future research areas for exploring new ways to extend the scope of the microfluidic approach in biofilm studies.

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“…While the flow in this figure only has a streamwise (lateral in the measurement frame) component, UIV can also characterise, for instance, the flow encountering a sudden diameter change . This opens up more sophisticated methods to establish rheological parameters (Drost and Westerweel 2013). Ultrasound-based velocimetry has also been successfully applied in Taylor-Couette flows, for more fundamental rheology studies (Manneville et al 2004).…”

Section: Miscellaneous Applicationsmentioning

confidence: 99%