Fluorinated Nanocomposite Coatings for Confinement and Pumpless Transport of Low‐Surface‐Tension Liquids

Morrissette, Jared M.; Ghosh, Aritra; Campos, Raymond; Mates, Joseph E.; Mabry, Joseph M.; Megaridis, Constantine M.

doi:10.1002/admi.201901105

Cited by 8 publications

(16 citation statements)

References 53 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To demonstrate, that the variety and complexity of shapes obtainable with this core–shell approach is comparable to LSTLs confined by omniphobic–omniphilic surfaces, we created several patterns with varying interior angles (60°, 90°, 120°) and a maze‐like structure (Figure 1C). [ 21,22,24,26 ] Compartments with an organic layer feature size down to 1 mm were fabricated.…”

Section: Resultsmentioning

confidence: 99%

“…[ 18–20 ] Furthermore, these methods often solely constrain the area wetted by the LSTL and there are only a few demonstrations of patterned LSTLs. [ 21–26 ] Jokinen et al. demonstrated the use of superhydrophobic–hydrophilic patterns to create designer multiphase droplets to confine an organic liquid droplet inside an aqueous droplet or for miniaturized liquid–liquid–liquid extraction application.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Liquid Wells as Self‐Healing, Functional Analogues to Solid Vessels

et al. 2021

View full text Add to dashboard Cite

Liquids are traditionally handled and stored in solid vessels. Solid walls are not functional, adaptive, or self‐repairing, and are difficult to remove and re‐form. Liquid walls can overcome these limitations, but cannot form free‐standing 3D walls. Herein, a liquid analogue of a well, termed a “liquid well” is introduced. Water tethered to a surface with hydrophobic–hydrophilic core–shell patterns forms stable liquid walls capable of containing another immiscible fluid, similar to fluid confinement by solid walls. Liquid wells with different liquids, volumes, and shapes are prepared and investigated by confocal and Raman microscopy. The confinement of various low‐surface‐tension liquids (LSTLs) on surfaces by liquid wells can compete with or be complementary to existing confinement strategies using perfluorinated surfaces, for example, in terms of the shape and height of the confined LSTLs. Liquid wells show unique properties arising from their liquid aggregate state: they are self‐healing, dynamic, and functional, that is, not restricted to a passive confining role. Water walls can be easily removed and re‐formed, making them interesting as sacrificial templates. This is demonstrated in a process termed water‐templated polymerization (WTP). Numerical phase‐field model simulations are performed to scrutinize the conditions required for the formation of stable liquid wells.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Liquid Wells as Self‐Healing, Functional Analogues to Solid Vessels

et al. 2021

View full text Add to dashboard Cite

show abstract

“…Another area for continued research and investigation is the application of wettability gradients to low-surface-tension liquids, where omnidirectional spreading behavior is more commonly seen. Clearly, a different approach is needed here to attain rapid, directional transport …”

Section: Passive Liquid-transport Mechanismsmentioning

confidence: 99%

“…Regime I resembled the early stage spreading of unconfined viscous droplets through hemiwicking, yielding Washburn spreading characteristics (i.e., X ∼ T 0.5 ); the second regime displayed a linear trend (i.e., X ∼ T), ensuing from a balance between the driving capillary force and the viscous resistive force; the third spreading regime followed a density-augmented Tanner spreading trend (i.e., X ∼ T 0.1 ), which arises when the spreading film thickness becomes thin enough so that the dissipation at the contact line dictates the spreading behavior. Such mode of capillary-driven transport on wedge-shaped wettability confined tracks was not restricted only to water droplets; the principle was also harnessed to transport low surface-tension liquids with γ lg as low as 23.8 mN/ m. 163 For a surface immersed in water, a similar design with opposite contrast of wettability (i.e., a superhydrophobic wedgetrack laid on a superhydrophilic background) was shown to induce capillary-driven transport of air bubbles dispensed underneath the wettability patterned surface. 164 Unlike the spreading of liquid droplets on a wedge track, propagation of the air-bubble front, however, showed a linear temporal variation; a scaling argument revealed that the spreading velocity for the bubble on the superhydrophobic wedge track arises from an inertia−capillary force balance and varies as the inverse of the square root of the track width.…”

Section: Transport Due To Surface Wettability Gradientmentioning

confidence: 99%

“…Liquid manipulation studies have primarily focused on surfaces where the wettability modification has been brought about through chemical functionalization, micro-and nanoscale roughness features, or a combination of both. 33,45,72,73,77,78,159,162,163 Roughness induced on such surfaces were random, which originated from mechanical or chemical etching and/or depositions of nanocomposites. A detailed account of liquid transport on such surfaces has already been provided in section 3.1. pattern i), whereas, the topographic gradients demonstrated by Shastry et al 102 consisted of square micropillars with silane and Teflon coatings; Figure 10, pattern ii.…”

Section: Flat Surfacesmentioning

confidence: 99%

See 1 more Smart Citation

Patterning Wettability for Open-Surface Fluidic Manipulation: Fundamentals and Applications

et al. 2022

Self Cite

View full text Add to dashboard Cite

Effective manipulation of liquids on open surfaces without external energy input is indispensable for the advancement of point-of-care diagnostic devices. Open-surface microfluidics has the potential to benefit health care, especially in the developing world. This review highlights the prospects for harnessing capillary forces on surface-microfluidic platforms, chiefly by inducing smooth gradients or sharp steps of wettability on substrates, to elicit passive liquid transport and higher-order fluidic manipulations without off-the-chip energy sources. A broad spectrum of the recent progress in the emerging field of passive surface microfluidics is highlighted, and its promise for developing facile, low-cost, easy-to-operate microfluidic devices is discussed in light of recent applications, not only in the domain of biomedical microfluidics but also in the general areas of energy and water conservation.

show abstract

Bioinspired Superwetting Open Microfluidics: From Concepts, Phenomena to Applications

et al. 2023

Adv Funct Materials

View full text Add to dashboard Cite

Microfluidics and bioinspired superwetting materials, as two crucial branches of scientific research, are entering their golden age of development. As an emerging interdisciplinary subject of these two fields, bioinspired superwetting open microfluidics is triggering technological revolutions in many disciplines, including rapid medical diagnosis, biochemical analysis, liquid manipulation, 3D printing, etc. However, this new research area has yet to attract extensive attention. So, a timely review is necessary to organize the development process, summarize current achievements, and discuss the challenges or chances for the ongoing scientific trend. In this review, the evolution from closed to open microfluidics is combed first. Then, three typical bioinspired superwetting systems are introduced emphatically. Based on this, the bioinspired superwetting open microfluidics is divided into different categories according to the bionic objects as the focus of this study. Taking natural phenomena as the entry point, the research from the underlying mechanism to the application is systematically discussed and summarized. Several emerging applications are also mentioned. Finally, some views on major problems, existing challenges, and developing trends are briefly put forward in this field to guide future research.

show abstract

Fluorinated Nanocomposite Coatings for Confinement and Pumpless Transport of Low‐Surface‐Tension Liquids

Cited by 8 publications

References 53 publications

Liquid Wells as Self‐Healing, Functional Analogues to Solid Vessels

Liquid Wells as Self‐Healing, Functional Analogues to Solid Vessels

Patterning Wettability for Open-Surface Fluidic Manipulation: Fundamentals and Applications

Bioinspired Superwetting Open Microfluidics: From Concepts, Phenomena to Applications

Contact Info

Product

Resources

About