The synthesis of higher-carbon sugar alcohols via indium-mediated acyloxyallylation as potential phase change materials

Markus Draskovits, Nina Biedermann, Marko D. Mihovilovic, Michael Schnürch, Christian Stanetty
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Abstract

In recent years, sugar alcohols have gained significant attention as organic phase change materials (PCMs) for thermal energy storage due to their comparably high thermal storage densities up to 350 J/g. In a computational study, outstandingly high values of up to ~ 450500 J/g have been postulated for specific higher-carbon sugar alcohols. These optimized structures feature an even number of carbon atoms in the backbone and a stereochemical configuration in which all hydroxyl groups are in an 1,3-anti-relationship, as found in the natural hexitol d-mannitol. However, these manno-configured higher-carbon sugar alcohols have not been experimentally investigated as PCMs yet and described synthetic routes are elaborate multiple steps syntheses. Therefore, we aimed to synthesize sugar alcohols of the manno-series with a concise synthetic protocol based on the indium-mediated acyloxyallylation (IMA) of aldoses. En route the C2-epimers were easily accessible, namely gluco-configured sugar alcohols, bearing one set of hydroxyl groups in a suboptimal 1,3-syn-realtionship. The synthesized compounds were found to possess thermal properties consistent with the predicted values, and the “perfect” higher-carbon sugar alcohol with eight carbon atoms was found to have indeed an outstanding high latent heat of fusion of ~ 380 J/g with a melting point of 260 °C.

Graphical abstract

Abstract Image

通过铟介导的酰氧基烯丙基化合成高碳糖醇作为潜在的相变材料
近年来,糖醇作为用于热能储存的有机相变材料(PCMs)受到了广泛关注,因为它们具有相当高的热储存密度,最高可达 350 焦耳/克。在一项计算研究中,人们推测特定的高碳糖醇具有高达约 450-500 焦耳/克的出色数值。这些优化结构的特点是骨架中碳原子数目均匀,立体化学构型中所有羟基都是 1,3-反关系,如天然己糖醇 d-甘露醇中的构型。然而,这些甘露构型的高碳糖醇尚未作为 PCM 进行实验研究,所描述的合成路线也是复杂的多步骤合成。因此,我们的目标是基于铟介导的醛酸酰氧基烯丙基化(IMA),采用简洁的合成方案合成甘露系列糖醇。在此过程中很容易获得 C2- 嵌合体,即葡萄糖构型糖醇,它们带有一组羟基,其 1,3-合成关系不理想。合成的化合物具有与预测值一致的热性质,而且发现具有 8 个碳原子的 "完美 "高碳糖醇确实具有约 380 焦耳/克的高熔化潜热,熔点为 260 °C。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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