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

Author

Listed:
  • Bhavana Deore

    (National Research Council Canada)

  • Kathleen L. Sampson

    (National Research Council Canada)

  • Thomas Lacelle

    (National Research Council Canada)

  • Nathan Kredentser

    (National Research Council Canada)

  • Jacques Lefebvre

    (National Research Council Canada)

  • Luke Steven Young

    (National Research Council Canada)

  • Joseph Hyland

    (Carleton University)

  • Rony E. Amaya

    (Carleton University)

  • Jamshid Tanha

    (National Research Council Canada)

  • Patrick R. L. Malenfant

    (National Research Council Canada)

  • Hendrick W. Haan

    (University of Ontario Institute of Technology)

  • Chantal Paquet

    (National Research Council Canada)

Abstract

3D printing has enabled materials, geometries and functional properties to be combined in unique ways otherwise unattainable via traditional manufacturing techniques, yet its adoption as a mainstream manufacturing platform for functional objects is hindered by the physical challenges in printing multiple materials. Vat polymerization offers a polymer chemistry-based approach to generating smart objects, in which phase separation is used to control the spatial positioning of materials and thus at once, achieve desirable morphological and functional properties of final 3D printed objects. This study demonstrates how the spatial distribution of different material phases can be modulated by controlling the kinetics of gelation, cross-linking density and material diffusivity through the judicious selection of photoresin components. A continuum of morphologies, ranging from functional coatings, gradients and composites are generated, enabling the fabrication of 3D piezoresistive sensors, 5G antennas and antimicrobial objects and thus illustrating a promising way forward in the integration of dissimilar materials in 3D printing of smart or functional parts.

Suggested Citation

  • Bhavana Deore & Kathleen L. Sampson & Thomas Lacelle & Nathan Kredentser & Jacques Lefebvre & Luke Steven Young & Joseph Hyland & Rony E. Amaya & Jamshid Tanha & Patrick R. L. Malenfant & Hendrick W. , 2021. "Direct printing of functional 3D objects using polymerization-induced phase separation," Nature Communications, Nature, vol. 12(1), pages 1-12, December.
  • Handle: RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-020-20256-3
    DOI: 10.1038/s41467-020-20256-3
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    Cited by:

    1. Valentin A. Bobrin & Yin Yao & Xiaobing Shi & Yuan Xiu & Jin Zhang & Nathaniel Corrigan & Cyrille Boyer, 2022. "Nano- to macro-scale control of 3D printed materials via polymerization induced microphase separation," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    2. Soosang Chae & Won Jin Choi & Lisa Julia Nebel & Chang Hee Cho & Quinn A. Besford & André Knapp & Pavlo Makushko & Yevhen Zabila & Oleksandr Pylypovskyi & Min Woo Jeong & Stanislav Avdoshenko & Oliver, 2024. "Kinetically controlled metal-elastomer nanophases for environmentally resilient stretchable electronics," Nature Communications, Nature, vol. 15(1), pages 1-12, December.
    3. Soo Young Cho & Dong Hae Ho & Yoon Young Choi & Soomook Lim & Sungjoo Lee & Ji Won Suk & Sae Byeok Jo & Jeong Ho Cho, 2022. "A general fruit acid chelation route for eco-friendly and ambient 3D printing of metals," Nature Communications, Nature, vol. 13(1), pages 1-9, December.

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