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羧酸结构对聚氨酯泡沫酸解制再生多元醇动力学的影响

Influence of Carboxylic Acid Structure on the Kinetics of Polyurethane Foam Acidolysis to Recycled Polyol.

作者信息

Westman Zach, Liu Baoyuan, Richardson Kelsey, Davis Madeleine, Lim Dingyuan, Stottlemyer Alan L, Letko Christopher S, Hooshyar Nasim, Vlcek Vojtech, Christopher Phillip, Abu-Omar Mahdi M

机构信息

Department of Chemical Engineering, University of California, Santa Barbara, Santa Barbara, California 93106-5080, United States.

Department of Chemistry and Biochemistry, University of California, Santa Barbara, Santa Barbara, California 93106-9510, United States.

出版信息

JACS Au. 2024 Aug 1;4(8):3194-3204. doi: 10.1021/jacsau.4c00495. eCollection 2024 Aug 26.

DOI:10.1021/jacsau.4c00495
PMID:39211586
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11350715/
Abstract

Closed-loop recycling of plastics is needed to bridge the gap between the material demands imposed by a growing global population and the depletion of nonrenewable petroleum feedstocks. Here, we examine chemical recycling of polyurethane foams (PUFs), the sixth most produced polymer in the world, through PUF acidolysis via dicarboxylic acids (DCAs) to release recyclable polyols. Acidolysis enables recycling of the polyol component of PUFs to high-quality materials, and while the influence of DCA structure on recycled PUF quality has been reported, there are no reports that examine the influence of DCA structure on the kinetics of polyol release. Here, we develop quantitative relationships between DCA structure and PUF acidolysis function for ∼10 different DCA reagents. PUF acidolysis kinetics were quantified with ∼1 s time resolution using the rate of carbon dioxide (CO) gas generation, which is shown to occur concomitantly with polyol release. Pseudo-zeroth-order rate constants were measured as a function of DCA composition, reaction temperature, and DCA concentration, and apparent activation barriers were extracted. Our findings demonstrate that DCA carboxyl group proximity and phase of transport are descriptors of PUF acidolysis rates, rather than expected descriptors like p . DCAs with closer proximity acid groups exhibited faster PUF acidolysis rate constants. Furthermore, a shrinking core mechanism effectively describes the kinetic functional form of the kinetics of PUF acidolysis by DCAs. Measurements of acidolysis kinetics for model PUF (M-PUF) and end-of-life PUF (EOL PUF) confirm the applicability of our analysis to postconsumer materials. This work provides insights into the physical and chemical mechanisms controlling acidolysis, which can facilitate the development of efficient closed-loop PUF chemical recycling schemes.

摘要

为了弥合全球人口增长带来的材料需求与不可再生石油原料枯竭之间的差距,需要对塑料进行闭环回收。在此,我们研究了聚氨酯泡沫(PUF)的化学回收,PUF是世界上产量第六高的聚合物,通过二元羧酸(DCA)对PUF进行酸解以释放可回收的多元醇。酸解能够将PUF的多元醇成分回收为高质量材料,虽然已经报道了DCA结构对回收PUF质量的影响,但尚无研究考察DCA结构对多元醇释放动力学的影响。在此,我们建立了约10种不同DCA试剂的DCA结构与PUF酸解功能之间的定量关系。使用二氧化碳(CO)气体生成速率以约1秒的时间分辨率对PUF酸解动力学进行了量化,结果表明CO气体生成与多元醇释放同时发生。测量了作为DCA组成、反应温度和DCA浓度函数的伪零级速率常数,并提取了表观活化能垒。我们的研究结果表明,DCA羧基的接近程度和传输相是PUF酸解速率的描述符,而不是像pKa这样的预期描述符。酸基更接近的DCA表现出更快的PUF酸解速率常数。此外,收缩核机制有效地描述了DCA对PUF酸解动力学的动力学功能形式。对模型PUF(M-PUF)和报废PUF(EOL PUF)的酸解动力学测量证实了我们的分析对消费后材料的适用性。这项工作为控制酸解的物理和化学机制提供了见解,有助于开发高效的闭环PUF化学回收方案。

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