4.7 Article

Inherent Flame-Retardant, Humid Environment Stable and Blue Luminescent Polyamide Elastomer Regulated by Siloxane Moiety

Journal

POLYMERS
Volume 14, Issue 9, Pages -

Publisher

MDPI
DOI: 10.3390/polym14091919

Keywords

polyamide copolymer; one-pot melt polycondensation; flame retardancy; hydrophobic character; blue luminescence

Funding

  1. Zhengzhou University Young Talent Enterprise Cooperation Innovation Team Support Program
  2. National Science Foundation for Young Scientists of China [51703206]
  3. Key Research and Development and Promotion Projects of Henan Province [152102310070, 202102210034]
  4. National Key Research and Development Program of China [2017YFB0307600]
  5. China Postdoctoral Science Foundation [2020M682317]
  6. Henan Postdoctoral Foundation [202002018]
  7. National Science Foundation of China [51973201]

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In this study, a series of novel silicone-containing polyamides were successfully synthesized, and their properties were regulated by the Si12 unit-content. The characterized chemical structure and physical properties revealed that the polyamides exhibited good elasticity, flame retardancy, and blue luminescence. These silicone-containing polyamides have promising application potential for high-performance polymeric materials.
The rapid development of the polymeric materials market has created an urgent demand for the thermoplastic polyamide elastomer (TPAE) owing to its greater functionality, and ability to be synthesized via a facile and industrial route. In this work, a series of novel silicone-containing polyamides (PA1212/Si12) were successfully synthesized from 1,12-dodecarboxylic acid (LA), 1,12-dodecarbondiamine (DMDA), and 1,3-bis (amino-propyl) tetramethyldisiloxane (BATS), via a one-pot melt polycondensation method in the absence of a catalyst. FTIR, H-1-NMR, GPC and inherent viscosity results cohesively prove that the polymerization of monomers was well conducted, and the chemical structure was in high accordance with the design. As expected, the Si12 unit-content of the copolymers regulate the properties of the series. As the feeding ratio of BATS in the diamines increases from 5 mol% to 40 mol%, the thermal transition temperatures, T-g and T-m, decline steadily before finally stabilizing at similar to 6 degrees C and 160 degrees C, respectively, indicating that the co-polyamides possess improved chain flexibility but restricted crystallization ability. The conspicuous evolution in crystalline morphology of the series was observed by XRD and AFM. The increased PA Si12 phase induces the crystallized PA 1212 phase to transit from a thermally-favorable large and rigid crystal structure (alpha phase) to a kinetically-favorable small and ductile crystal structure (gamma phase). Reflected in their stress-strain behavior, PA1212/Si12 copolymers are successfully tailored from rigid plastic to ductile elastomer. The tensile strength mildly drops from above 40 MPa to --30 MPa while the reversible elongation increases from similar to 50% to approximately 350%. Accordingly, the moderate surface tension differences in the monomers facilitate the efficient conduction of the co-polymerization process, and the distributed short siloxane unit in the backbone fulfills the copolymer with desirable elasticity. Interestingly, the novel silicone-containing polyamides also display Si12 unit-content dependent flame retardancy, humidity stability, and unconventional solid-state fluorescence properties. The elastomers exhibit a low bibulous rate and anti-fouling characteristics to dye droplets and mud contamination, pass the V-1 rating (UL 94) with a constantly declining PHRR value, and emit blue luminescence under a 365 nm light source. Herein, we propose a new facile strategy for developing a high-performance and multifunctional silicone-modified polyamide, which bears promising industrialization potential. In addition, this first reported silicone-containing thermoplastic polyamide elastomer, which is self-extinguishing, anti-fouling and blue-luminescent, will further broaden the application potential of thermoplastic polyamide elastomers.

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