Droplets Crawling on Peristome‐Mimetic Surfaces

Zhou, Shaolin; Yu, Cunlong; Li, Chuxin; Jiang, Lei; Dong, Zhichao

doi:10.1002/adfm.201908066

Cited by 17 publications

(19 citation statements)

References 42 publications

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“…The zwitterion polymer (2-methacryloyloxyethyl phosphorylch cation flowchart is shown in Figure 3. The bionic replica of the PDMS treated by plasma cleaning for 1 min (Figure 3a) and then immerse (Figure 3b) [27,28]. In addition to activating the surface functional gro treatment can effectively improve the uniformity of the modification pre-treated PDMS was treated by oxygen atmospheric plasma (AP P Electronic Co., Ltd., Taipei, Taiwan) (Figure 3c) to polymerize the MPC polymer brushes (Figure 3d) at an operating power of 1.2 kW and ox slm (L/min) for 10 s, and a 1.2 cm distance was maintained from the p…”

Section: Mpc Immobilization By Atmospheric Plasmamentioning

confidence: 99%

“…The zwitterion polymer (2-methacryloyloxyethyl phosphorylcholine, MPC) modification flowchart is shown in Figure 3. The bionic replica of the PDMS membrane was pre-treated by plasma cleaning for 1 min (Figure 3a) and then immersed in MPC solution (Figure 3b) [27,28]. In addition to activating the surface functional groups, the hydrophilic treatment can effectively improve the uniformity of the modification.…”

Section: Mpc Immobilization By Atmospheric Plasmamentioning

confidence: 99%

“…The plane structure is reproduced on PDMS through transfer-printing technology [13,26,27]. Most studies choose PDMS as the transfer material due to its excellent pattern reproduction accuracy, easy preparation, and ease of observation, etc.…”

Section: Introductionmentioning

confidence: 99%

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Replica of Bionic Nepenthes Peristome-like and Anti-Fouling Structures for Self-Driving Water and Raman-Enhancing Detection

Lin

Syu

et al. 2022

Polymers

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The flexible, anti-fouling, and bionic surface-enhanced Raman scattering (SERS) biochip, which has a Nepenthes peristome-like structure, was fabricated by photolithography, replicated technology, and thermal evaporation. The pattern of the bionic Nepenthes peristome-like structure was fabricated by two layers of photolithography with SU-8 photoresist. The bionic structure was then replicated by polydimethylsiloxane (PDMS) and grafting the zwitterion polymers (2-methacryloyloxyethyl phosphorylcholine, MPC) by atmospheric plasma polymerization (PDMS-PMPC). The phospholipid monomer of MPC immobilization plays an important role; it can not only improve hydrophilicity, anti-fouling and anti-bacterial properties, and biocompatibility, but it also allows for self-driving and unidirectional water delivery. Ag nanofilms (5 nm) were deposited on a PDMS (PDMS-Ag) substrate by thermal evaporation for SERS detection. Characterizations of the bionic SERS chips were measured by a scanning electron microscope (SEM), optical microscope (OM), X-ray photoelectron spectrometer (XPS), Fourier-transform infrared spectroscopy (FTIR), and contact angle (CA) testing. The results show that the superior anti-fouling capability of proteins and bacteria (E. coli) was found on the PDMS-PMPC substrate. Furthermore, the one-way liquid transfer capability of the bionic SERS chip was successfully demonstrated, which provides for the ability to separate samples during the flow channel, and which was detected by Raman spectroscopy. The SERS intensity (adenine, 10−4 M) of PDMS-Ag with a bionic structure is ~4 times higher than PDMS-Ag without a bionic structure, due to the multi-reflection of the 3D bionic structure. The high-sensitivity bionic SERS substrate, with its self-driving water capability, has potential for biomolecule separation and detection.

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Section: Mpc Immobilization By Atmospheric Plasmamentioning

confidence: 99%

Section: Mpc Immobilization By Atmospheric Plasmamentioning

confidence: 99%

See 1 more Smart Citation

Replica of Bionic Nepenthes Peristome-like and Anti-Fouling Structures for Self-Driving Water and Raman-Enhancing Detection

Lin

Syu

et al. 2022

Polymers

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“…59,61 Experimental and numerical studies have characterized the directional transportation of these unique structures in terms of surface wettability, as well as the viscosity and surface tension of the liquid. [66][67][68][69][70] In 2017, Chen et al 6 also fabricated bio-inspired unidirectional liquid spreading surfaces using inclined UV exposure of SU-8 photoresist. Various arc-curvatures and wedge angles were fabricated to investigate the effect of structural features on the spread mechanism (Fig.…”

Section: Bio-mimetic Wedge Corner Structuresmentioning

confidence: 99%

Anisotropy-induced directional self-transportation of low surface tension liquids: a review

Soltani

Golovin

2020

RSC Adv.

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“…Revealing the mechanisms behind these natural occurrences not only helps to solve the annoying problems of liquid overflow and splashing events that occur in daily life [ 12–14 ] but also inspires the innovative applications, such as agricultural irrigation, pesticide sprays, fog collection, lubrication, printing, microfluidic operation, soft robotics, oil–water separation, seawater desalination, biomedicine, microreactor, self‐assembly, and energy conversion. [ 2,15–31 ]…”

Section: Introductionmentioning

confidence: 99%

Bioinspired Surface with Superwettability for Controllable Liquid Dynamics

Zhou

Jiang

Dong

2020

Adv Materials Inter

Self Cite

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Liquid dynamics on a solid surface, i.e., the impact, flow, or overflow, are ubiquitous in nature and cause multifaceted problems that affect daily life. Recent studies on the role of surface superwettability in controlling liquid dynamics have attracted much attention. The role of particular surface morphologies and surface chemical compositions in manipulating the liquid impact or transport dynamics has garnered diverse scientific interests and has encouraged the widespread use of surface wettabilities in practical applications. Herein, the recent progress according to the interaction method between the liquid and solid is classified and summarized. The crucial influence of surface wettabilities and structures on liquid dynamic behaviors and a critical survey of the mechanism behind these behaviors, along with emerging applications, challenges, and perspectives, are presented.

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Droplets Crawling on Peristome‐Mimetic Surfaces

Cited by 17 publications

References 42 publications

Replica of Bionic Nepenthes Peristome-like and Anti-Fouling Structures for Self-Driving Water and Raman-Enhancing Detection

Replica of Bionic Nepenthes Peristome-like and Anti-Fouling Structures for Self-Driving Water and Raman-Enhancing Detection

Anisotropy-induced directional self-transportation of low surface tension liquids: a review

Bioinspired Surface with Superwettability for Controllable Liquid Dynamics

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