Intensification of fructose dehydration into 5‐HMF and subsequent oxidation to 2,5‐FDCA using ultrasound

Danwyn J. Aranha, Madhuri M. Kininge, P. Gogate
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Abstract

Ultrasound‐assisted dehydration of fructose into 5‐hydroxymethylfurfural (5‐HMF) and subsequent oxidation to furandicarboxylic acid (2, 5‐FDCA) is studied in the current work with the main objective being to elucidate the effectiveness of ultrasound for intensified synthesis. The effect of reaction parameters like ultrasound power, duty cycle, reaction time, reaction temperature, solid to solvent ratio, and fructose concentration on the dehydration of fructose into 5‐HMF has been studied. Optimized conditions established were ultrasonic power of 140 W, duty cycle of 60%, reaction time of 60 min, temperature of 100°C, and fructose:dimethylsulfoxide (DMSO) ratio of 3:100 (g/mL), which resulted in the highest 5‐HMF yield of 96% and fructose conversion of 100%. The conventional method carried out at optimized conditions resulted in only 13.5% as 5‐HMF yield. The obtained 5‐HMF was further oxidized to FDCA using Pd/C as the catalyst, H2O/DMSO as solvent, and K2CO3 as a base also using ultrasonic irradiation at 140 W power and 22 kHz frequency in the presence and absence of O2 as oxidant. 100% conversion of 5‐ HMF was obtained in 30 min and 4 h using ultrasound in the presence of O2 and in absence of O2, respectively. 75% conversion of 5‐HMF was observed using the conventional method in 5 h in the presence of O2. Overall, the intensification benefits of using ultrasound at both steps of synthesis has been successfully elucidated.
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利用超声波强化果糖脱水成 5-HMF 以及随后氧化成 2,5-FDCA 的过程
目前的工作研究了超声辅助果糖脱水成 5-hydroxymethylfurfural (5-HMF) 以及随后氧化成呋喃二甲酸 (2,5-FDCA) 的过程,主要目的是阐明超声在强化合成中的有效性。研究了超声功率、占空比、反应时间、反应温度、固体与溶剂比率和果糖浓度等反应参数对果糖脱水成 5-HMF 的影响。优化条件为超声波功率为 140 W,占空比为 60%,反应时间为 60 分钟,温度为 100°C,果糖与二甲基亚砜(DMSO)的比例为 3:100(克/毫升)。而在优化条件下采用传统方法制备的 5-HMF 收率仅为 13.5%。以 Pd/C 为催化剂,H2O/DMSO 为溶剂,K2CO3 为碱液,同时使用 140 W 功率和 22 kHz 频率的超声波辐照,在氧气作为氧化剂存在和不存在的情况下,将得到的 5-HMF 进一步氧化为 FDCA。在有 O2 和无 O2 的情况下,使用超声波分别在 30 分钟和 4 小时内实现了 5- HMF 的 100% 转化。在有 O2 存在的情况下,使用传统方法在 5 小时内可观察到 75% 的 5-HMF 转化率。总之,在合成的两个步骤中使用超声波的强化优势已被成功阐明。
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