2022
DOI: 10.1002/adfm.202211317
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Sustainable Droplet Manipulation on Ultrafast Lubricant Self‐Mediating Photothermal Slippery Surfaces

Abstract: Designing intelligent slippery surfaces for droplet manipulation is critical for many applications from drug delivery to bio‐analysis, while is of great challenging in sustainability for inescapable wastage of lubricant layer. Herein, an ultrafast lubricant self‐mediating (self‐replenishing/‐absorbing) photothermal slippery surface is designed that achieves sustainable transport of droplet under the irradiation of near infrared light (NIL) even if the lubricant layer is wiped clean completely, as well as at ot… Show more

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Cited by 26 publications
(21 citation statements)
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“…[6][7][8] To serve this purpose, static approaches that integrates asymmetric surface textures have been devised to passively alter the dimension, direction, and velocity of droplet transport on designated functional surfaces. [9][10][11][12][13][14] Furthermore, surfaces incorporating stimulus-responsive elements that respond to electrical, [15][16][17][18] magnetic, 19-21 thermal [22][23][24] and acoustic [25][26][27] stimuli are endowed with intelligent functionalities to manipulate the mobility of residing droplets by reversible structural restructuring and chemical reactions. Most notably, electrowetting-on-dielectric (EWOD), 28,29 electro-dewetting 15,30 or opto-electrowetting 31,32 systems can transport discrete droplets by exploiting interactions between the solution and elec-tried surfaces.…”
Section: Introductionmentioning
confidence: 99%
“…[6][7][8] To serve this purpose, static approaches that integrates asymmetric surface textures have been devised to passively alter the dimension, direction, and velocity of droplet transport on designated functional surfaces. [9][10][11][12][13][14] Furthermore, surfaces incorporating stimulus-responsive elements that respond to electrical, [15][16][17][18] magnetic, 19-21 thermal [22][23][24] and acoustic [25][26][27] stimuli are endowed with intelligent functionalities to manipulate the mobility of residing droplets by reversible structural restructuring and chemical reactions. Most notably, electrowetting-on-dielectric (EWOD), 28,29 electro-dewetting 15,30 or opto-electrowetting 31,32 systems can transport discrete droplets by exploiting interactions between the solution and elec-tried surfaces.…”
Section: Introductionmentioning
confidence: 99%
“…Inspired by the liquid directional transport of biological surfaces, both active and passive artificial surfaces capable of directional liquid transportation have been developed. The bionic liquid directional transport surface simulates the excellent form and composition of biological surfaces and shows the superior characteristic of liquid directional transport. Moreover, liquid transport can be controlled by adjusting feature structures or surface energy under external stimuli, e.g. , temperature, light, , electric, magnetism, , stretch, etc . Among them, surface curvature is easy to operate, environmentally friendly, and promising for manipulating liquids. Despite many studies that have been conducted on surface wettability control, there are still challenges to achieving real-time transformation of liquid transport with switchable direction on the material surface.…”
mentioning
confidence: 99%
“…15−18 The bionic liquid directional transport surface simulates the excellent form and composition of biological surfaces and shows the superior characteristic of liquid directional transport. 19−24 Moreover, liquid transport can be controlled by adjusting feature structures or surface energy under external stimuli, e.g., temperature, 25−27 light, 28,29 electric, 30 magnetism, 31,32 stretch, 33−37 etc. Among them, surface curvature is easy to operate, environmentally friendly, and promising for manipulating liquids.…”
mentioning
confidence: 99%
“…8,11 However, the generated microdroplets are tightly anchored on the highly adhesive or hydrophilic regions, confining its applicability to in situ analysis and detection only. Active droplet splitting techniques leverage electricity, 9,12 magnets, 13,14 acoustics, 15 and light 16,17 to split droplets and some of them could also enable transport of the generated microdroplet. However, most of them can divide a droplet into two microdroplets in a single operation, making it difficult to achieve a high-throughput implementation.…”
mentioning
confidence: 99%
“…For example, the droplet can be split by impacting it on patterned superhydrophobic–hydrophilic surfaces or patterned adhesive surfaces, with which the droplet could be fragmented into a preset number of microdroplets and deposited with a designated arrangement for simultaneous arrayed reactions. , However, the generated microdroplets are tightly anchored on the highly adhesive or hydrophilic regions, confining its applicability to in situ analysis and detection only. Active droplet splitting techniques leverage electricity, , magnets, , acoustics, and light , to split droplets and some of them could also enable transport of the generated microdroplet. However, most of them can divide a droplet into two microdroplets in a single operation, making it difficult to achieve a high-throughput implementation.…”
mentioning
confidence: 99%