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Abstract
Microfabrication strategies designed to produce ordered arrangements of colloidal particles on solid supports are of great interest in materials science and technology due to their wide range of applications, from plasmonic and biomimetic surfaces to tags for anti-counterfeiting and goods identification. Existing methods allow excellent control over particle organization yet share a degree of complexity hampering their facile implementation. Here we present a simple methodology for creating ordered particle arrays on solid substrates only requiring the deposition on the target substrate of a colloidal suspension drop and flipping it upside-down for particle sedimentation, self-organization at air/water interface and evaporation-driven deposition. Particle adsorption at the air/water interface, here enabled by the addition of small amount of cationic surfactants, is critical to ensure two-dimensional confinement of repulsive particles and their self-assembly into extended ordered arrays prior to complete solvent evaporation and particle transfer to the substrate. We demonstrate the versatility of the method by the creation of arrays of various kinds of particles (silica, polystyrene) with diameters in the range 300 nm – 5 µm on different target substrates (polystyrene, polydimethylsiloxane, glass) as well as the generation of a variety of patterns. The size and morphology of the deposit, from single-crystals to multi-crystalline patches, can be controlled by the curvature of the drop and the total number of particles, while more complex colloidal structures, like colloidal crystal “alloys” and “irises” can be achieved by successive depositions, co-crystallization or double flipping.
Supplementary materials
Title
Supporting Information PDF File
Description
This file includes:
- Materials and methods section
- Supplementary figures S1–S11
- Legends of the movies S1–S7
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Title
Movie S1. Drying of a hanging drop, transmission microscopy.
Description
Drop composition: 560 nm diameter silica particles, Cp = 0.05 mg/mL, Vdrop = 5 µL, Cs = 10 µM. The drop was deposited on a polystyrene substrate and turned upside-down before recording the video. The actual time (min:sec) is displayed in the top left corner. Scale bar: 300 μm.
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Title
Movie S2. Drying of a hanging drop, side-view transmission microscopy.
Description
Drop composition: 560 nm diameter silica particles, Cp = 0.05 mg/mL, Vdrop = 5 µL, Cs = 10 µM. The drop was deposited on a polystyrene substrate and the video was started 12 minutes after turning the drop upside-down. The actual time (min:sec) is displayed in the top left corner. Scale bar: 300 μm.
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Title
Movie S3. Drying of a hanging drop, reflection microscopy.
Description
Drop composition: 560 nm diameter silica particles, Cp = 0.05 mg/mL, Vdrop = 5 µL, Cs = 10 µM. The drop was deposited on a polystyrene substrate and the video was started 5 minutes after turning the drop upside-down. The actual time (min:sec) is displayed in the top left corner. Scale bar: 300 μm.
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Title
Movie S4. Crystallization in a hanging drop, transmission microscopy.
Description
Drop composition: 2.4 µm diameter silica particles, Cp = 0.05 mg/mL, Vdrop = 2.5 µL, Cs = 5 µM. The drop was deposited on a polystyrene substrate and the video was started 5 minutes after turning the drop upside-down. Focused frames were manually selected from z-stack acquisition done every 2 minutes in order to follow the air/water interface during the evaporation process. Scale bar: 100 μm.
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Title
Movie S5. Drying of a hanging drop in the absence of surfactants in suspension.
Description
Drop composition: 560 nm diameter silica particles, Cp = 0.05 mg/mL, Vdrop = 5 µL. The drop was deposited on a polystyrene substrate and turned upside-down before recording the video in transmission mode. The actual time (min:sec) is displayed in the top left corner. Scale bar: 300 μm.
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Movie S6. Drying of a hanging drop on a PDMS substrate.
Description
Drop composition: 560 nm diameter silica particles, Cp = 0.05 mg/mL, Vdrop = 5 µL, Cs = 10 µM. The drop was deposited on a PDMS substrate and the video was started in reflection mode 82 minutes after turning the drop upside-down. Focus was manually adjusted to follow the particle assembly at the air/water interface during the evaporation process. The actual time (min:sec) is displayed in the top left corner. Scale bar: 300 μm.
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Title
Movie S7. Fabrication of a polycrystalline colloidal “iris”.
Description
Drop composition: 560 nm diameter silica particles, Cp = 0.05 mg/mL, Vdrop = 5 µL, Cs = 10 µM. The drop was deposited on a polystyrene substrate the video was started in reflection mode approx. 1 hour after turning the drop upside-down. The drop was turned back in sessile configuration 4 minutes after starting the recording. After the second flipping, the focus was manually adjusted to the drop contact line. The actual time (min:sec) is displayed in the top left corner. Scale bar: 300 μm.
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