Facile fabrication of hydrolysis resistant phosphite antioxidants for high-performance optical PET films via in situ incorporation

[Display omitted] •LDH can considerably enhance hydrolysis resistance of the phosphite antioxidants.•Hybridized phosphite antioxidants enhance optical transmittances of optical PET.•Hybridized phosphite antioxidants improve antioxidation performances of optical PET.•The chromaticity of as-created op...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2017-11, Vol.328, p.406-416
Main Authors: Sun, Shuai, Wang, Lipeng, Song, Pingan, Ding, Liping, Bai, Yongping
Format: Article
Language:English
Subjects:
Chromaticity
Hydrolysis resistance
Optical PET
Phosphites antioxidants
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Summary:[Display omitted] •LDH can considerably enhance hydrolysis resistance of the phosphite antioxidants.•Hybridized phosphite antioxidants enhance optical transmittances of optical PET.•Hybridized phosphite antioxidants improve antioxidation performances of optical PET.•The chromaticity of as-created optical PET films is prominently enhanced. Phosphite antioxidants are extensively used in polyester industry due to extraordinary antioxidative and chromaticity protection capabilities. Unfortunately, they are highly susceptible to hydrolysis leading to reduced antioxidative activity, which remains unsatisfactorily addressed so far. In this work, we have demonstrated the fabrication of hydrolysis resistant hybridized phosphite antioxidants (PSLDH) by physically melt-blending with layered double hydroxides (LDH) based on the hydrolysis mechanism. X-ray diffraction measurements indicate that basically phosphite antioxidants are physically hybridized with the LDH. Accelerated hydrolysis results show that as-fabricated hybridized phosphite antioxidants show much superior anti-hydrolysis capability to the unmodified counterpart because the basic LDH can neutralize the phosphoric acid created during hydrolysis, thus effectively prohibiting the self-catalytic effect. High performance optical poly(ethylene terephthalate) (PET) materials are then synthesized by in situ adding PSLDH in the polycondensation process. Only adding 0.05wt% of the PSLDH containing 10wt% of LDH can remarkably improve the anti-oxidative and chromaticity performances of the resultant PET. This work provides an innovative methodology for developing high-performance value-added chemical additives via facile physical hybridization.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2017.07.070