Light-Controlled Particle Enrichment Patterns in Droplets

Li, Dongliang; Li, Wei; Chen, Rong; Zhu, Xun; Ye, Dingding; Yang, Yang; Liu, Qiang

doi:10.1021/acs.analchem.3c00763

Cited by 4 publications

(2 citation statements)

References 37 publications

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“…1–6 One prevalent approach for facilitating droplet directional transport involves the design of surfaces with non-uniform wetting characteristics, incorporating gradients in either chemical composition or topography. 7–9 The natural world is a valuable source of inspiration in developing advanced materials for manipulating droplets. 10–12 As an illustration, rice leaves exhibit bidirectional anisotropic wettability, allowing water droplets to traverse along the leaf veins under self-gravity, ultimately enhancing the survival of rice plants under drought conditions.…”

Section: Introductionmentioning

confidence: 99%

Efficient fabrication of bioinspired soft, ridged-slippery surfaces with large-range anisotropic wettability for droplet manipulation

Jiao,

Tan,

et al. 2024

Soft Matter

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Section: Introductionmentioning

confidence: 99%

Efficient fabrication of bioinspired soft, ridged-slippery surfaces with large-range anisotropic wettability for droplet manipulation

Jiao,

Tan,

et al. 2024

Soft Matter

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“…Microdroplet manipulation on solid surfaces holds promise for applications in surface patterning [7][8][9][10], microreactors [11][12][13][14][15], and bioassays [16][17][18][19][20]. Their motions are driven by external optical [21][22][23][24], thermal [25][26][27][28], electrical [29][30][31][32], and magnetic [33][34][35][36] stimuli. Optical stimulation has the advantage of allowing remote and directional control of motion.…”

Section: Introductionmentioning

confidence: 99%

Visualization of the Dynamics of Photoinduced Crawling Motion of 4-(Methylamino)Azobenzene Crystals via Diffracted X-ray Tracking

Saito,

Ichiyanagi,

Fukaya

et al. 2023

IJMS

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The photoinduced crawling motion of crystals is a continuous motion that azobenzene molecular crystals exhibit under light irradiation. Such motion enables object manipulation at the microscale with a simple setup of fixed LED light sources. Transportation of nano-/micromaterials using photoinduced crawling motion has recently been reported. However, the details of the motion mechanism have not been revealed so far. Herein, we report visualization of the dynamics of fine particles in 4-(methylamino)azobenzene (4-MAAB) crystals under light irradiation via diffracted X-ray tracking (DXT). Continuously repeated melting and recrystallization of 4-MAAB crystals under light irradiation results in the flow of liquid 4-MAAB. Zinc oxide (ZnO) particles were introduced inside the 4-MAAB crystals to detect diffracted X-rays. The ZnO particles rotate with the flow of liquid 4-MAAB. By using white X-rays with a wide energy width, the rotation of each zinc oxide nanoparticle was detected as the movement of a bright spot in the X-ray diffraction pattern. It was clearly shown that the ZnO particles rotated increasingly as the irradiation light intensity increased. Furthermore, we also found anisotropy in the rotational direction of ZnO particles that occurred during the crawling motion of 4-MAAB crystals. It has become clear that the flow perpendicular to the supporting film of 4-MAAB crystals is enhanced inside the crystal during the crawling motion. DXT provides a unique means to elucidate the mechanism of photoinduced crawling motion of crystals.

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Massive Electro‐Microfluidic Particle Assembly Patterns in Droplet Array for Information Encoding

Feng,

Shen,

Jin

et al. 2024

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The assembly of colloidal particles into micro‐patterns is essential in optics, informatics, and microelectronics. However, it is still a challenge to achieve quick, reversible, and precise assembly patterns within micro‐scale spaces like droplets. Hereby, a method is presented that utilizes in‐plane dielectrophoresis to precisely manipulate particle assemblies within microscale droplets. The electro–microfluidic particle assembly platform, equipped with ingenious electrode designs, enables the formation of diverse micro‐patterns within a droplet array. The tunability, similarity, stability, and reversibility of this platform are demonstrated. The ability to assemble letters, numbers, and Morse code patterns within the droplet array underscores its potential for information encoding. Furthermore, using an example with four addressing electrodes beneath a droplet, 16 distinct pieces of information through electrical stimuli is successfully encoded. This unique capability facilitates the construction of a dynamic electronic token, indicating promising applications in anti‐counterfeiting technologies.

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Light-Controlled Particle Enrichment Patterns in Droplets

Cited by 4 publications

References 37 publications

Efficient fabrication of bioinspired soft, ridged-slippery surfaces with large-range anisotropic wettability for droplet manipulation

Efficient fabrication of bioinspired soft, ridged-slippery surfaces with large-range anisotropic wettability for droplet manipulation

Visualization of the Dynamics of Photoinduced Crawling Motion of 4-(Methylamino)Azobenzene Crystals via Diffracted X-ray Tracking

Massive Electro‐Microfluidic Particle Assembly Patterns in Droplet Array for Information Encoding

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