Apparent Contact Angles on Lubricant-Impregnated Surfaces/SLIPS: From Superhydrophobicity to Electrowetting

McHale, Glen; Orme, Bethany V.; Wells, Gary G.; Ledesma‐Aguilar, Rodrigo

doi:10.1021/acs.langmuir.8b04136

Cited by 89 publications

(114 citation statements)

References 45 publications

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“…On liquid-infused surfaces, the apparent contact angle of a droplet depends on the surface tensions and the intrinsic contact angles of all fluids involved in the system [24][25][26] . This rich interplay makes it much less trivial to predict the direction of droplet motion when there is a topographical gradient.…”

Section: Resultsmentioning

confidence: 99%

“…To determine the direction of droplet motion, we can introduce the droplet-air effective interfacial tension 26 γ eff γ oa þ γ ow ; if S > 0ð lubricant encapsulation Þ; γ wa ; otherwise ; & and the following definitions of apparent contact angles cos θ eff wajs…”

Section: Resultsmentioning

confidence: 99%

“…Alternatively, we can determine cos θ eff wajs and cos θ eff wajo using a graphical method as follows. In the vanishing meniscus approximation, the droplet apparent contact angle on the composite solid-lubricant surface can be expressed as 24,26 cos θ app ¼ γ ðs;oÞa À γ ðs;oÞw…”

Section: Resultsmentioning

confidence: 99%

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Bidirectional motion of droplets on gradient liquid infused surfaces

et al. 2020

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The current paradigm of self-propelled motion of liquid droplets on surfaces with chemical or topographical wetting gradients is always mono-directional. In contrast, here, we demonstrate bidirectional droplet motion, which we realize using liquid infused surfaces with topographical gradients. The deposited droplet can move either toward the denser or the sparser solid fraction area. We rigorously validate the bidirectional phenomenon using various combinations of droplets and lubricants, and different forms of structural/topographical gradients, by employing both lattice Boltzmann simulations and experiments. We also present a simple and physically intuitive analytical theory that explains the origin of the bidirectional motion. The key factor determining the direction of motion is the wettability difference of the droplet on the solid surface and on the lubricant film.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Bidirectional motion of droplets on gradient liquid infused surfaces

et al. 2020

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“…The contact angle of a droplet on a surface can be regulated by a voltage between the electrodes, which is called the electrowetting effect [110]. This electromechanical mechanism dominates the microfluidic behavior by modifying the interfacial tension [111]. More relevant to the bearing working conditions, it is observed that the nonpolar dielectric lubricant in the contact area of a steel ball and a metallic layer will spread along the surface under the action of an electric field [112].…”

Section: Interfacial Stress Induced By Electric Field: Electrowettingmentioning

confidence: 99%

Electrical bearing failures in electric vehicles

2020

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In modern electric equipment, especially electric vehicles, inverter control systems can lead to complex shaft voltages and bearing currents. Within an electric motor, many parts have electrical failure problems, and among which bearings are the most sensitive and vulnerable components. In recent years, electrical failures in bearing have been frequently reported in electric vehicles, and the electrical failure of bearings has become a key issue that restricts the lifetime of all-electric motor-based power systems in a broader sense. The purpose of this review is to provide a comprehensive overview of the bearing premature failure in the mechanical systems exposed in an electrical environment represented by electric vehicles. The electrical environments in which bearing works including the different components and the origins of the shaft voltages and bearing currents, as well as the typical modes of electrical bearing failure including various topographical damages and lubrication failures, have been discussed. The fundamental influence mechanisms of voltage/current on the friction/ lubrication properties have been summarized and analyzed, and corresponding countermeasures have been proposed. Finally, a brief introduction to the key technical flaws in the current researches will be made and the future outlook of frontier directions will be discussed.

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“…When the lubricant encapsulates the droplet, the effective droplet-gas surface tension becomes g eff dg = g lg + g ld . 32 3…”

Section: 12mentioning

confidence: 99%