Magnetic resonance imaging of flow and mass transfer in electrohydrodynamic liquid bridges

Wexler, Adam D.; Drusová, Sandra; Fuchs, Elmar; Woisetschläger, Jakob; Reiter, Gert; Fuchsjäger, Michael; Reiter, Ursula

doi:10.1007/s12650-016-0379-1

Cited by 9 publications

(12 citation statements)

References 24 publications

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“…3b), and its bi-directionality is clearly shown by the thermal video (SV 3) and the mass transport in the beakers (more details in Appendix B). Specifically, the maximum velocity [20] is comparable with the maximum flow velocity in order of tens of millimeters per second (Fig. 9b).…”

Section: Discussion and Outlookmentioning

confidence: 59%

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Armstrong Liquid Bridge: Formation, Evolution and Breakup

Pan,

Hu,

et al. 2021

Preprint

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In this paper, we experimentally explore the formation, evolution and breakup of Armstrong liquid bridge. The extremely complicated evolution stage is revealed, which involves many coupled processes including the morphology change, current variation, heat transfer, and water evaporation. By focusing on the final fate of this liquid bridge, we observe that the breakup occurs once an effective length ( L) is reached. This effective length increases linearly with the applied voltage, implying a threshold electric field to sustain the liquid bridge. Moreover, by an introduced external flow, the lifetime of the liquid bridge can be controlled, while the effective length associated with the breakup is independent on the external flow rate. Hence, these findings remarkably demonstrate that the breakup of liquid bridge is directly correlated with the effective length. In order to understand this correlation, a simplified model of an electrified jet is employed to take the electric field into account. By the linear stability analysis, the attained phase diagram agrees with the experiments well. Although a more comprehensive theory is required to consider other factors such as the surface charges, these results might provide a fresh perspective on the "century-old" Armstrong liquid bridge to further elucidate its underlying physical mechanism.

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Section: Discussion and Outlookmentioning

confidence: 59%

“…Secondly, during the evolution stage, the bi-directional axial flow was observed using magnetic resonance imaging [20], and was explained by the electro-osmotic flow due to the charges on the outer surface of the liquid bridge [16].…”

Section: Discussion and Outlookmentioning

confidence: 99%

Armstrong Liquid Bridge: Formation, Evolution and Breakup

Pan,

Hu,

et al. 2021

Preprint

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“…As motivated by the recent visualizations of bidirectional flow [28], we have considered, in addition to bulk charges, a spatial modulation of the radial charge distribution such that a surface potential occurs. Solving the Navier-Stokes equation leads to a modified mass flow through the bridge.…”

Section: Discussionmentioning

confidence: 99%

“…Since both mass and charge transport are coupled, here we find the possibility that the mass transport might show a reverse behavior dependent on the parameters. This study is motivated by the bidirectional flow visualized recently in [28] and measured with mass and charge transfer in [29].…”

Section: Introductionmentioning

confidence: 99%

Reversed Currents in Charged Liquid Bridges

Morawetz

2017

Water

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Abstract:The velocity profile in a water bridge is reanalyzed. Assuming hypothetically that the bulk charge has a radial distribution, a surface potential is formed that is analogous to the Zeta potential. The Navier-Stokes equation is solved, neglecting the convective term; then, analytically and for special field and potential ranges, a sign change of the total mass flow is reported caused by the radial charge distribution.

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“…Formal relationships between the physical fluid parameters, electric field intensity, and experimental configuration have been worked out by Marín and Lohse [7]. Later Morawetz [8][9][10] successfully modelled the bridge as a charged catenary, and his considerations concerning the flow profile match the experimental findings of Wexler et al [11]. Aerov [12], on the other hand, proposed a model where surface tension is responsible for holding the bridge against the gravity.…”

Section: Introductionmentioning

confidence: 96%

Electrically Induced Liquid–Liquid Phase Transition in a Floating Water Bridge Identified by Refractive Index Variations

Fuchs¹,

Woisetschläger

Wexler

et al. 2021

Water

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A horizontal electrohydrodynamic (EHD) liquid bridge (also known as a “floating water bridge”) is a phenomenon that forms when high voltage DC (kV·cm−1) is applied to pure water in two separate beakers. The bridge, a free-floating connection between the beakers, acts as a cylindrical lens and refracts light. Using an interferometric set-up with a line pattern placed in the background of the bridge, the light passing through is split into a horizontally and a vertically polarized component which are both projected into the image space in front of the bridge with a small vertical offset (shear). Apart from a 100 Hz waviness due to a resonance effect between the power supply and vortical structures at the onset of the bridge, spikes with an increased refractive index moving through the bridge were observed. These spikes can be explained by an electrically induced liquid–liquid phase transition in which the vibrational modes of the water molecules couple coherently.

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Magnetic resonance imaging of flow and mass transfer in electrohydrodynamic liquid bridges

Cited by 9 publications

References 24 publications

Armstrong Liquid Bridge: Formation, Evolution and Breakup

Armstrong Liquid Bridge: Formation, Evolution and Breakup

Reversed Currents in Charged Liquid Bridges

Electrically Induced Liquid–Liquid Phase Transition in a Floating Water Bridge Identified by Refractive Index Variations

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