Highly Efficient Multiscale Fog Collector Inspired by Sarracenia Trichome Hierarchical Structure

Chen, Huawei; Ran, Tong; Zhang, Kaiteng; Chen, Dengke; Gan, Yang; Wang, Zelinlan; Jiang, Lei

doi:10.1002/gch2.202100087

Cited by 15 publications

(13 citation statements)

References 45 publications

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“…For rough solid surfaces, the deposited liquid droplets exhibit three kinds of classic wetting models: the Wenzel state, Cassie–Baxter state, and hemiwicking state, which are determined by the surface structure and interfacial interactions of liquids and solids. − In the hemiwicking state, the fluid spontaneously imbibes or wicks along the narrow micro-/nanostructured roughness ahead of the fluid droplet under the balance of the capillary force and the viscous force, like wicking behaviors. In recent years, the wicking phenomenon, including wicking and hemiwicking, has attracted increasing attention for its significance in engineering applications, such as thermal management, − water harvesting, − fuel cells, microfluidics, − and biosciences, in which the wicking behavior determined by micro-/nanostructures plays a critical role in the process of liquid transportation. The mechanism of the wicking process is rather complex, mainly involved in the competition of the drive of the capillary force and the hindering of the viscous force, both of which favor smaller length scales.…”

Section: Introductionmentioning

confidence: 99%

Anisotropic Hemiwicking Behavior on Laser Structured Prismatic Microgrooves

et al. 2022

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The wicking phenomenon, including wicking and hemiwicking, has attracted increasing attention for its critical importance to a wide range of engineering applications, such as thermal management, water harvesting, fuel cells, microfluidics, and biosciences. There exists a more urgent demand for anisotropic wicking behaviors since an increasing number of advanced applications are significantly complex. For example, special-shaped vapor chambers and heating atomizers in some electronic cigarettes need liquid replenishing with various velocities in different directions. Here, we report two-dimensional anisotropic hemiwicking behaviors with elliptical shapes on laser structured prismatic microgrooves. The prismatic microgrooves were fabricated via one-step femtosecond laser direct writing, and the anisotropic hemiwicking behaviors were observed when utilizing glycerol, glycol, and water as the test liquid. Specifically, the ratios of horizontal wicking distance in directions along short and long axes were tan 0°, tan 15°, tan 30°, and tan 45° for samples with cross-angles of 0°, 30°, 60°, and 90°, respectively. The vertical water wicking front displayed corresponding angles under the guidance of laser structured prismatic microgrooves. Theoretical analysis shows that the wicking distance is mainly dependent on the cross-angle θ and surface roughness, in which the wicking distance is proportional to cos(θ/2). Driven by the capillary pressure forming in the narrow microgrooves, the liquid initially filled the valleys of microgrooves and then surrounded and covered the prismatic ridges with laser-induced nanoparticles. The abundant nanoparticles increased the surface roughness, leading to the enhancement of wicking performance, which was further evidenced by the larger wicking speed of the sample with more nanoparticles. The mechanism of anisotropic hemiwicking behaviors revealed in this work paves the way for wicking control, and the proposed prismatic microgrooved surfaces with two-dimensional anisotropic hemiwicking performance and superhydrophilicity could serve in a broad range of applications, especially for the advanced thermal management with specific heat load configurations.

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Section: Introductionmentioning

confidence: 99%

Anisotropic Hemiwicking Behavior on Laser Structured Prismatic Microgrooves

et al. 2022

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“…The ultrafast liquid transport has been found on the Sarracenia trichome, and its unique HMC with high–low ribs has also been proved to play a great role in fog capture and harvesting. , In order to reveal the influence of different HMCs, the needles with N high ribs and n low ribs are set under the same saturated fog flow of 0.35 m/s. Fluorescent particles were doped in saturated fog and activated by ultraviolet light to better observe the fog harvest process.…”

Section: Resultsmentioning

confidence: 99%

High-Efficient Fog Harvest from a Synergistic Effect of Coupling Hierarchical Structures

Zhang

Chen

Ran

et al. 2022

ACS Appl. Mater. Interfaces

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Fog harvesting is an important method to solve the water shortage in arid and semi-arid areas by collecting water from air. Improving fog harvesting efficiency is still a big challenge to be overcome. Herein, under the inspiration of natural creatures, a novel harvesting structure that couples a hierarchical microchannel (HMC) needle with the Janus membrane by taking a conical pore as their junction is proposed. Such an HMC-conical pore-Janus membrane system can improve the harvesting efficiency by regulation of liquid behavior in the whole fog harvesting process involving droplet capture from air, high speed transport on the microchannel, and droplet detachment from Janus. The synergistic effects of the hierarchical channel-conical pore-Janus structure are exploited in terms of capture, transport, and detachment capabilities, and their underlying mechanism to enhance fog harvesting efficiency is built. Compared with the traditional harvesting structure, the proposed hierarchical channel-conical-Janus coupling mode was demonstrated to improve fog harvesting efficiency by 90%. Such a coupled system has potential applications in efficient fog harvesting systems, microfluidic devices, and liquid manipulation.

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“…The artificial trichome can harvest fog ultrafast and transfer water against gravity like the genuine Sarracenia trichome. 108 Wang et al 106 reported a subulate Cu sheet with Sarracenia-like multilevel microchannels and cactus spines developed by pulsed laser direct structuring for continuous and high-performance water collection (Figure 9f). This unique combined structure (a spine with barbs and hierarchical channels) presented the highest fog harvesting speed (513 μg s −1 ) compared to the hierarchical channels (315 μg s −1 ), the spine with barbs and grooves (340 μg s −1 ), and the spine with barbs (377 μg s −1 ).…”

Section: Sarracenia Trichomes and Its Bioinspired Materialsmentioning

confidence: 99%

“…The major channels were constructed by an inner gear pattern, while the junior microchannels were automatically generated because of the assembly of glass fiber monofilaments. The artificial trichome can harvest fog ultrafast and transfer water against gravity like the genuine Sarracenia trichome 108 . Wang et al 106 reported a subulate Cu sheet with Sarracenia ‐like multilevel microchannels and cactus spines developed by pulsed laser direct structuring for continuous and high‐performance water collection (Figure 9f).…”

Section: Water Transport Using Hydrophilic Surfacesmentioning

confidence: 99%

Bioinspired superwetting materials for water manipulation

Leng

Sun

Long

et al. 2022

Droplet

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Water manipulation is crucial for a wide range of engineering applications, such as microfluidics, heat transfer, desalination, and water harvesting. Despite scientific achievements in the past few decades, it remains challenging to achieve efficient and well‐controllable droplet transport in practical applications. In nature, creatures have evolved ingenious wisdom to manipulate water to adapt to their environments. Learning from nature and combining bioinspirations with advanced manufacturing technology are promising to fabricate excellent materials for directional water transport. In this review, we summarize the mechanisms of water droplet manipulation on various biological surfaces and review the recent progress in fabricating hydrophilic surfaces, hybrid hydrophilic/hydrophobic surfaces, and slippery lubricant‐infused porous surfaces (SLIPSs) with bioinspiration for water manipulation. These novel bioinspired materials have great potential in many fields, especially for water harvesting. Finally, current challenges and future perspectives in this field are proposed.

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Highly Efficient Multiscale Fog Collector Inspired by Sarracenia Trichome Hierarchical Structure

Cited by 15 publications

References 45 publications

Anisotropic Hemiwicking Behavior on Laser Structured Prismatic Microgrooves

Anisotropic Hemiwicking Behavior on Laser Structured Prismatic Microgrooves

High-Efficient Fog Harvest from a Synergistic Effect of Coupling Hierarchical Structures

Bioinspired superwetting materials for water manipulation

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