Direct printing of functional 3D objects using polymerization-induced phase separation

Deore, Bhavana; Sampson, Kathleen L.; Lacelle, Thomas; Kredentser, Nathan; Jacques, Laurent; Young, Luke Steven; Hyland, Joseph; Amaya, Rony E.; Tanha, Jamshid; Malenfant, Patrick R. L.; Haan, Hendrick W. de; Paquet, Chantal

doi:10.1038/s41467-020-20256-3

Cited by 55 publications

(52 citation statements)

References 52 publications

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“…Besides pattern generation, photopolymerization also induces phase separation of NPs toward the surface. This phenomenon has previously been reported using silicon NPs, 25 semiconductor nanocrystals, 28 silver decanoate, 29 silica NPs, 30 polymer blends, 31 − 33 and polymer–solvent systems. 9 , 15 Figure 1 b also shows a magnified view of a single bump, indicating the expected outward movement of NPs from the polymer-rich regions to monomer-rich regions (namely upward to the surface) owing to PIPS, which is key to good surface coverage.…”

Section: Resultssupporting

confidence: 78%

Superhydrophobic Polymer Composite Surfaces Developed via Photopolymerization

Pathreeker

Chando

Chen

et al. 2021

ACS Appl. Polym. Mater.

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Fabrication of superhydrophobic materials using incumbent techniques involves several processing steps and is therefore either quite complex, not scalable, or often both. Here, the development of superhydrophobic surface-patterned polymer–TiO 2 composite materials using a simple, single-step photopolymerization-based approach is reported. The synergistic combination of concurrent, periodic bump-like pattern formation created using irradiation through a photomask and photopolymerization-induced nanoparticle (NP) phase separation enables the development of surface textures with dual-scale roughness (micrometer-sized bumps and NPs) that demonstrate high water contact angles, low roll-off angles, and desirable postprocessability such as flexibility, peel-and-stick capability, and self-cleaning capability. The effect of nanoparticle concentration on surface porosity and consequently nonwetting properties is discussed. Large-area fabrication over an area of 20 cm 2 , which is important for practical applications, is also demonstrated. This work demonstrates the capability of polymerizable systems to aid in the organization of functional polymer–nanoparticle surface structures.

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Section: Resultssupporting

confidence: 78%

Superhydrophobic Polymer Composite Surfaces Developed via Photopolymerization

Pathreeker

Chando

Chen

et al. 2021

ACS Appl. Polym. Mater.

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“…20,[39][40][41][42] As of late, it has been effectively applied in the fabrication of micro/-nanoporous materials, such as glass and polymers, using SLA. [43][44][45][46][47] In this paper, we report the SLA 3D printing of thin superhydrophobic membranes (100-400 mm) with adjustable porosity in the submicron range with 30 nm to 300 nm pores. The process combines both, required topography and surface chemistry for achieving superhydrophobicity in a single step.…”

Section: Introductionmentioning

confidence: 99%

Facile fabrication of micro-/nanostructured, superhydrophobic membranes with adjustable porosity by 3D printing

Mayoussi¹,

Doeven

Kick³

et al. 2021

J. Mater. Chem. A

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“…IME technology is anticipated to be a game changer in the production of 3D human‐machine interfaces (HMIs) for consumer electronics, home appliances, automotive and aerospace applications ( Figure a,b). The potential of producing 3D electronic devices directly from multi‐material 3D printing is in its infancy and promises to take shape in the future, [ 23 ] but from today's manufacturing perspective IME is interesting because it utilizes traditional, high volume processes to print functional inks on flat, 2D substrates which are thermoformed into 3D shapes and subsequently injection molded to produce a functional, lightweight and lower cost part or device (Figure 1c–e). However, in the transition from 2D to 3D during thermoforming, the traces must undergo elongation and strain at temperatures above the glass transition temperature of the substrates and remain conductive after the part is shaped and cooled.…”

Section: Introductionmentioning

confidence: 99%

UV‐Sinterable Silver Oxalate‐Based Molecular Inks and Their Application for In‐Mold Electronics

Fukutani

et al. 2021

Adv Elect Materials

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A new broadband UV light‐based processing method for a screen printable silver oxalate molecular ink is developed that enables structural electronics to be produced on complex thermoformed 3D objects. The production of these 3D devices is driven by the light‐induced reduction of silver oxalate to form an interfacial silver nanoparticle layer that allows the ink to transition to a viscous liquid intermediate and elongate up to 50% without cracking during thermoforming. Ultimately, this enables the development of 3D electronics devices with significantly less limitations on geometry, shape, size, and depth in comparison to commercially available inks. UV processing is also effective for 2D traces on low temperature PET substrate, where in situ produced silver nanoparticles can subsequently absorb light and further facilitate the rapid conversion of the silver oxalate to metallic silver through a self‐limiting thermal decomposition. The resulting traces have superior electrical properties and are produced in significantly less time in comparison to thermal sintering. Together, UV processing and the silver oxalate molecular ink serve as a platform for both the rapid production of conductive silver traces on low temperature substrates and the development of novel thermoformed 3D human‐machine interface devices, areas of interest for both academia and industry.

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Direct printing of functional 3D objects using polymerization-induced phase separation

Cited by 55 publications

References 52 publications

Superhydrophobic Polymer Composite Surfaces Developed via Photopolymerization

Superhydrophobic Polymer Composite Surfaces Developed via Photopolymerization

Facile fabrication of micro-/nanostructured, superhydrophobic membranes with adjustable porosity by 3D printing

UV‐Sinterable Silver Oxalate‐Based Molecular Inks and Their Application for In‐Mold Electronics

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