DeJaco Robert F, Bai Peng, Tsapatsis Michael, Siepmann J Ilja
Department of Chemical Engineering and Materials Science, ‡Chemical Theory Center, and §Department of Chemistry, University of Minnesota , Minneapolis, Minnesota 55455, United States.
Langmuir. 2016 Mar 1;32(8):2093-101. doi: 10.1021/acs.langmuir.5b04483. Epub 2016 Feb 15.
Anaerobic fermentation can transform carbohydrates to yield a multicomponent mixture comprising mainly of acetone, 1-butanol, and ethanol (ABE) in a typical weight ratio of 3:6:1. Compared to ethanol, 1-butanol, the main product of ABE fermentation, offers significant advantages as a biofuel or a fuel additive. However, the toxicity of 1-butanol for cell cultures requires broth concentrations to be low in 1-butanol (≈1-2 wt %). An energy-efficient recovery method that performs well even at low 1-butanol concentrations is therefore necessary to ensure economic feasibility of the ABE fermentation process. In this work, configurational-bias Monte Carlo simulations in the Gibbs ensemble are performed to probe the adsorption of 1-butanol/water solutions onto all-siliceous zeolites with the framework types MFI and FER. At low solution concentration, the selectivity and capacity for 1-butanol in MFI are larger than those in FER, while the opposite is true for concentrations at or above those of ABE broths. Structural analysis at various loadings sheds light on the different sorbate-sorbate and sorbate-sorbent interactions that govern trends in adsorption in each zeolite.
厌氧发酵可将碳水化合物转化为一种多组分混合物,主要包含丙酮、1-丁醇和乙醇(ABE),其典型重量比为3:6:1。与乙醇相比,作为ABE发酵主要产物的1-丁醇,作为生物燃料或燃料添加剂具有显著优势。然而,1-丁醇对细胞培养物具有毒性,这要求发酵液中1-丁醇的浓度较低(约1-2 wt%)。因此,需要一种即使在低1-丁醇浓度下也能良好运行的节能回收方法,以确保ABE发酵过程的经济可行性。在这项工作中,在吉布斯系综中进行构型偏倚蒙特卡罗模拟,以探究1-丁醇/水溶液在具有MFI和FER骨架类型的全硅沸石上的吸附情况。在低溶液浓度下,MFI中对1-丁醇的选择性和容量大于FER中的,而对于ABE发酵液浓度及以上的情况则相反。对不同负载量下的结构分析揭示了不同的吸附质-吸附质和吸附质-吸附剂相互作用,这些相互作用决定了每种沸石中吸附趋势。