Nanoscale Features of Zeolite Fillers Enhance the Depth of Cure, Optical Properties, and Mechanical Properties of 3D-Printed Polymer Composite Structures

Gao, Yuanyuan; Zhang, Yijun; Lalevée, Jacques; Simon‐Masseron, Angélique

doi:10.1021/acsanm.3c01073

Cited by 4 publications

(3 citation statements)

References 57 publications

(99 reference statements)

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“…[27] These light sources cure the resin by either selectively exposing it to light, or by projecting an image of the 3D model onto the resin layer. Several works have been done by our team using visible LED light (Light-Emitting Diode) to fabricate structured zeolite adsorbents for adsorption [28][29][30] and ion-exchange [31] applications. However, adding fillers to the photopolymerizable resin will cause light penetration issues since the filler particles can reflect, absorb, or scatter the light.…”

Section: Introductionmentioning

confidence: 99%

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Zeolite/Polymer Composites Prepared by Photopolymerization: Effect of Compensation Cations on Opacity and Gas Adsorption Applications

Gao,

Karatas,

Nouali

et al. 2024

Chemistry A European J

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The fabrication of structured zeolite adsorbents through photopolymerization‐based 3D printing which offers a solution to the limitations of conventional shaping techniques has been demonstrated but many parameters still need to be optimized. In this study, we studied the influence of zeolite compensation cations on the photopolymerization and the composite’s properties. Modified zeolites (LTA 4A and FAU 13X exchanged with K+, Li+, Sr2+, Ca2+ or Mg2+) were incorporated in PEGDA with BDMK as photoinitiator, and the formulation was cured under mild conditions (LED@405 nm, room temperature, under air). Our results indicate that the nature of zeolite compensation cations affects the colorimetric properties of polymer/zeolite composites: a better translucency parameter results in higher depth of cure. After calcination at 650 °C and complete removal of PEGDA, pure zeolitic monoliths were tested for adsorption of gas molecules of interest (carbon dioxide, dichlorobenzene and water). Structured 4A and 13X monoliths obtained by 3D printing exhibit comparable adsorption capacity to commercial beads prepared from the same zeolites. This study enhances our understanding of the photopolymerization process involved in the production of polymer/zeolite composites. These composites are used in the fabrication of zeolitic objects through 3D printing, offering potential solutions to various environmental and dental challenges.

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Section: Introductionmentioning

confidence: 99%

“…PEGDA was selected as monomer in this work due to its high polymerization conversion, good compatibility with zeolite and improved light transmittance for the composite. [30] The effects of cations on the photopolymerization, the adsorption and optical properties (particularly the colorimetric properties) are studied.…”

Section: Introductionmentioning

confidence: 99%

Zeolite/Polymer Composites Prepared by Photopolymerization: Effect of Compensation Cations on Opacity and Gas Adsorption Applications

Gao,

Karatas,

Nouali

et al. 2024

Chemistry A European J

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“…In recent works realized by our team, the zeolite content of LTA or FAU has reached 95 wt % using PEGDA as a monomer, BDMK as a photoinitiator, and toluene as solvent . The influence of the zeolite crystal size and Si/Al ratio on photopolymerization was studied, and the water vapor adsorption capacity of the printed monoliths was investigated . Inorganic binders such as Al 2 O 3 and SiO 2 were tested to improve the mechanical property of zeolitic monolith and introduce hierarchical porosity after calcination for different applications. , …”

Section: Introductionmentioning

confidence: 99%

Optimization of a Polymer/Zeolite-Based Composite Formulation Prepared via Photopolymerization under Near-UV/Visible Light

Gao,

Morlet-Savary,

Réty

et al. 2023

ACS Appl. Eng. Mater.

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In recent years, there has been growing interest in the preparation of structured polymer/zeolite composites via photopolymerization under UV/visible light. However, there is a lack of systematic study on formulation optimization, including the interaction between zeolite and photoinitiators as well as the selection of monomers. In this study, we investigated five acrylate/ methacrylate monomers, two photoinitiators, and four zeolites of different frameworks and compensation cations. The photopolymerization kinetics, depth of cure (DOC), and colorimetric properties of the polymer/zeolite composites were examined. Furthermore, the calcination parameters such as temperatures and atmospheres were explored. This calcination process is crucial for applications such as gas adsorption and catalysis, where the removal of the polymer is necessary to release zeolite porosity. The results demonstrated that the polymerization kinetics was influenced by zeolite's acidity, depending on the choice of photoinitiator. Additionally, the photoinitiators could further affect the specific surface areas of the calcined composites. PEGDA emerged as the most suitable polymer matrix due to its superior compatibility with zeolites, leading to homogeneous zeolite distribution and smooth surface characteristics after calcination. This work allows a better understanding of zeolite−resin interactions and highlights the influence of essential parameters and compounds on the characteristics of the structured nanoporous composites. This is a significant advance in the development of zeolite-based composites and of the process of zeolite shaping through photopolymerization.

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Physical, mechanical, and electrical conductivity characteristics of coconut shell-based H3PO4-Activated carbon/epoxy nanocomposites

Dungani,

Aditiawati,

Alamsyah

et al. 2024

Case Studies in Chemical and Environmental Engineering

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Nanoscale Features of Zeolite Fillers Enhance the Depth of Cure, Optical Properties, and Mechanical Properties of 3D-Printed Polymer Composite Structures

Cited by 4 publications

References 57 publications

Zeolite/Polymer Composites Prepared by Photopolymerization: Effect of Compensation Cations on Opacity and Gas Adsorption Applications

Zeolite/Polymer Composites Prepared by Photopolymerization: Effect of Compensation Cations on Opacity and Gas Adsorption Applications

Optimization of a Polymer/Zeolite-Based Composite Formulation Prepared via Photopolymerization under Near-UV/Visible Light

Physical, mechanical, and electrical conductivity characteristics of coconut shell-based H3PO4-Activated carbon/epoxy nanocomposites

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