Liquid-Phase Furfural Hydrogenation over Ni/Alumina Catalysts

IF 7.3 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

ACS Sustainable Chemistry & Engineering Pub Date : 2025-02-12 DOI:10.1021/acssuschemeng.4c0947710.1021/acssuschemeng.4c09477

Jim Mensah, Deshetti Jampaiah, Mohamed H. M. Ahmed, Muxina Konarova, Lee J. Durndell, Suresh K. Bhargava, Adam F. Lee* and Karen Wilson*,

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Abstract

Furfural is an important platform chemical for producing value-added biobased molecules and materials as alternatives to fossil-derived chemical building blocks. Furfuryl alcohol (FALC) is one such valuable product, whose sustainable synthesis requires the catalytic reduction of furfural over Earth-abundant elements under mild conditions. Here, we report the liquid-phase hydrogenation of furfural over Ni nanoparticles prepared by either wet impregnation of alumina or exsolution from a NiAl layered double hydroxide (LDH). Exsolved and calcined Ni nanoparticles (NPs) spanned 11–18 nm, whereas the wet impregnation of [γ+δ]Al₂O₃ yielded large Ni particles (24–101 nm) indicative of weak metal–support interactions. All catalysts exhibited moderate acid loadings (0.3–0.9 mmol·g^–1) and weak basicity. Furfural conversion at 10 bar H₂ and 165 °C is inversely proportional to Ni particle size and structure-insensitive. Ni metal is the active site for furfural hydrogenation to FALC (specific activity of 84 mmol.g_(Ni)^–1·h^–1 for NiAl-LDH, six times faster than Al₂O₃-supported Ni analogues with similar loading, and superior to many precious metal catalysts). FALC was the primary product at isoconversion with 60% selectivity but prone to secondary reactions at high furfural conversion, notably hydrogenolysis to 2-methylfuran (2-MF) or ring hydrogenation to tetrahydrofuryl alcohol (THFA). THFA was itself susceptible to hydrodeoxygenation over small Ni NPs at 10 bar H₂ in the presence of an acidic support to form 2-methyltetrahydrofuran (2-MTHF) via a previously unreported pathway. Higher hydrogen pressures favored FALC ring hydrogenation to THFA. Furfural hydrogenation to FALC was structure-insensitive for Ni NPs spanning 11–101 nm; however, secondary reactions of FALC were structure-sensitive. LDH-derived catalysts with 11 nm Ni NPs achieved a high yield of 2-MTHF (73%), a green solvent, liquid electrolyte, and high-density fuel additive. Furfural inhibited ring hydrogenation of reactively formed FALC (versus its hydrogenolysis or HDO), suppressing THFA and 2-MTHF production. However, ring hydrogenation of reactively formed FALC is favored at 25 bar H₂, albeit with THFA, the dominant product.

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Ni/氧化铝催化剂上的液相糠醛加氢

糠醛是一种重要的平台化学品，用于生产增值生物基分子和材料，作为化石来源的化学基石的替代品。糠醇（FALC）就是这样一种有价值的产品，它的可持续合成需要在温和的条件下在地球上丰富的元素上催化还原糠醛。在这里，我们报道了糠醛在湿浸渍氧化铝或从NiAl层状双氢氧化物（LDH）中析出制备的Ni纳米颗粒上的液相加氢反应。析出和煅烧的Ni纳米颗粒（NPs）跨度为11-18 nm，而湿浸渍的[γ+δ]Al2O3则产生较大的Ni颗粒（24-101 nm），表明弱金属-载体相互作用。所有催化剂均表现出中等酸性负荷（0.3 ~ 0.9 mmol·g-1）和弱碱性。在10 bar H2和165℃下，糠醛转化率与Ni颗粒大小成反比，且对结构不敏感。Ni金属是糠醛加氢生成FALC的活性位点（NiAl-LDH的比活度为84 mmol.g(Ni) -1·h-1，比负载相同的al2o3负载的Ni类似物快6倍，优于许多贵金属催化剂）。FALC是等转化的主要产物，选择性为60%，但在高糠醛转化时容易发生二次反应，特别是氢解生成2-甲基呋喃（2-MF）或环加氢生成四氢呋喃醇（THFA）。THFA本身在酸性载体存在下，在10 bar H2条件下对小Ni np进行加氢脱氧，通过先前未报道的途径形成2-甲基四氢呋喃（2-MTHF）。较高的氢压力有利于FALC环加氢生成THFA。糠醛加氢制FALC对11 ~ 101 nm的Ni NPs结构不敏感；然而，FALC的二次反应是结构敏感的。具有11 nm Ni NPs的ldh衍生催化剂获得了2-MTHF（73%）的高收率，这是一种绿色溶剂，液体电解质和高密度燃料添加剂。糠醛抑制反应生成的FALC的环加氢（相对于其氢解或HDO），抑制THFA和2-MTHF的产生。然而，在25 bar H2条件下，反应形成的FALC更倾向于环加氢，尽管主要产物是THFA。

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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来源期刊

ACS Sustainable Chemistry & Engineering CHEMISTRY, MULTIDISCIPLINARY-ENGINEERING, CHEMICAL

CiteScore

13.80

自引率

4.80%

发文量

1470

审稿时长

1.7 months

期刊介绍： ACS Sustainable Chemistry & Engineering is a prestigious weekly peer-reviewed scientific journal published by the American Chemical Society. Dedicated to advancing the principles of green chemistry and green engineering, it covers a wide array of research topics including green chemistry, green engineering, biomass, alternative energy, and life cycle assessment. The journal welcomes submissions in various formats, including Letters, Articles, Features, and Perspectives (Reviews), that address the challenges of sustainability in the chemical enterprise and contribute to the advancement of sustainable practices. Join us in shaping the future of sustainable chemistry and engineering.