Transient and steady shapes of droplets attached to a surface in a strong electric field

Reznik, S. N.; Yarin, Alexander L.; Théron, A.; Zussman, Eyal

doi:10.1017/s0022112004000679

Cited by 204 publications

(119 citation statements)

References 55 publications

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“…At increasing applied voltages, the shape of the ejected liquid (jet or spindle) seems to be affected by its wetting properties. 15 The pulsating regime is manifested at higher voltages and involves liquid ejection at higher frequencies than in the dripping regime. Standing waves on the meniscus surface are responsible for the ejection of liquid jets 16 at a frequency close to that given by Rayleigh's dispersion relation.…”

Section: Introductionmentioning

confidence: 99%

Electrospray Characteristic Curves: In Pursuit of Improved Performance in the Nanoflow Regime

2007

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Depending on its coordinates in the parameter space, an electrospray can manifest in one of several known regimes -stable, quasi-stable, transitional-chaotic, and non-axial -that ultimately impact measurement sensitivity and precision. An electrospray operating in cone-jet regime provides large and stable spray current, as well as smaller initial droplets that are prerequisites for higher sensitivity and quality mass spectrometric analyses. However, the dynamic conditions encountered in gradient elution-based liquid separations create difficulties for continuous operation in this regime throughout the analysis. We present a preliminary study aimed at stabilizing the electrospray in the cone-jet regime. On the basis of spray current measurements obtained using solvent conditions typically found in liquid chromatography-mass spectrometry, an improved description of the cone-jet stability island is provided by including transitions to and from the recently described astable regime. Additionally, the experimental conditions in which the astable regime marks the transition between pulsating and cone-jet regimes are further clarified.

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Section: Introductionmentioning

confidence: 99%

Electrospray Characteristic Curves: In Pursuit of Improved Performance in the Nanoflow Regime

2007

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“…10 These numerical investigations examined the impact of permittivity ratios and nonlinear polarization on interface shape, the impact of hysteresis on interface shape, and the problem of a nonconducting drop in a perfectly conducting medium. In other works, Stone et al 11 investigated interface shape using the slender body theory, Reznik et al 12 and Suvorov and Zubarev 13 examined the shape evolution of an electrified interface over time, and Cherney 14 investigated the structure of the Taylor cone and the emitted jet using perturbation methods.…”

Section: Introductionmentioning

confidence: 99%

Plane model of fluid interface rupture in an electric field

et al. 2008

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Modeling of an air-fluid interface in an electric field is presented. Specifically, equilibrium of the interface under the dominant forces-electric stress, surface tension, and pressure-is investigated. Since interface shape and equilibrium are related, the shape of an electrified interface is also addressed. To determine the electric stress, an analytical expression for the electric field in the vicinity of the interface is determined. The operating point of the interface is shown to exist in a three-dimensional parameter space that is divided by a critical surface into equilibrium, quasiequilibrium, and nonequilibrium subdomains. The three parameters are applied voltage, electrode separation, and pressure difference. Interface size, counterelectrode size, and fluid properties are also considered. The subdomain in which the operating point resides defines the important characteristics of the interface. The operating point moves within, and transfers between, equilibrium subdomains, and points on the critical surface represent "rupture points" of the interface. The final shape of the interface is solved iteratively using this equilibrium model. Interfaces emitting an electrospray can have a range of apex angles, and it is shown that the magnitude of this angle impacts equilibrium. It is revealed that the excess pressure difference term is critical in determining the interface shape ͑specifically the cone generatrix͒ and that minimization of the potential energy of all forces can be used to predict the magnitude of the apex angle and pressure immediately after interface rupture. The equilibrium model is important from an operational and optimization perspective, as it is useful to predict the conditions required to break equilibrium and transfer to a quasiequilibrium state ͑i.e., an electrospray͒, and the conditions necessary to maintain quasiequilibrium once it is formed.

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“…Ammonia follows sp 3 hybridization and it has extra pair of electrons. This electron plays a major role in sensing because this paired electron from ammonia and formaldehyde passes to the sample at room temperature.…”

Section: Reasons For Not Sensing At Room Temperaturementioning

confidence: 99%

Nanocomposite Fibers Sensor

Regius¹

2014

IOSRJAP

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Transient and steady shapes of droplets attached to a surface in a strong electric field

Cited by 204 publications

References 55 publications

Electrospray Characteristic Curves: In Pursuit of Improved Performance in the Nanoflow Regime

Electrospray Characteristic Curves: In Pursuit of Improved Performance in the Nanoflow Regime

Plane model of fluid interface rupture in an electric field

Nanocomposite Fibers Sensor

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