Alexander Francesca M, Fonrouge Sergio F, Borioni José L, Del Pópolo Mario G, Horton Peter N, Coles Simon J, Hutchings Benjamin P, Crawford Deborah E, James Stuart L
School of Chemistry and Chemical Engineering, Queen's University Belfast David Keir Building, Stranmillis Road Belfast BT7 1NN UK
ICB-CONICET, Facultad de Ciencias Exactas y Naturales, Universidad Nacional de Cuyo Padre Jorge Contreras 1300 Mendoza M5502 JMA Argentina.
Chem Sci. 2021 Oct 14;12(42):14230-14240. doi: 10.1039/d1sc03367k. eCollection 2021 Nov 3.
Porous Liquids (PLs) are a new class of material that possess both fluidity and permanent porosity. As such they can act as enhanced, selective solvents and may ultimately find applications which are not possible for porous solids, such as continuous flow separation processes. Type II PLs consist of empty molecular hosts dissolved in size-excluded solvents and to date have mainly been based on hosts that have limited chemical and thermal stability. Here we identify Noria, a rigid cyclic oligomer as a new host for the synthesis of more robust Type II PLs. Although the structure of Noria is well-documented, we find that literature has overlooked the true composition of bulk Noria samples. We find that bulk samples typically consist of Noria ( 40%), a Noria isomer, specifically a resorcinarene trimer, "R3" ( 30%) and other unidentified oligomers ( 30%). Noria has been characterised crystallographically as a diethyl ether solvate and its H NMR spectrum fully assigned for the first time. The previously postulated but unreported R3 has also been characterised crystallographically as a dimethyl sulfoxide solvate, which confirms its alternative connectivity to Noria. Noria and R3 have low solubility which precludes their use in Type II PLs, however, the partially ethylated derivative Noria-OEt dissolves in the size-excluded solvent 15-crown-5 to give a new Type II PL. This PL exhibits enhanced uptake of methane (CH) gas supporting the presence of empty pores in the liquid. Detailed molecular dynamics simulations support the existence of pores in the liquid and show that occupation of the pores by CH is favoured. Overall, this work revises the general accepted composition of bulk Noria samples and shows that Noria derivatives are appropriate for the synthesis of more robust Type II PLs.
多孔液体(PLs)是一类新型材料,兼具流动性和永久孔隙率。因此,它们可作为增强的选择性溶剂,最终可能找到多孔固体无法实现的应用,如连续流分离过程。II型PLs由溶解在尺寸排阻溶剂中的空分子主体组成,迄今为止主要基于化学和热稳定性有限的主体。在这里,我们确定刚性环状低聚物诺里亚(Noria)是合成更稳定的II型PLs的新型主体。尽管诺里亚的结构已有充分记录,但我们发现文献忽略了块状诺里亚样品的真实组成。我们发现块状样品通常由诺里亚(40%)、一种诺里亚异构体,具体为间苯二酚芳烃三聚体“R3”(30%)和其他未鉴定的低聚物(30%)组成。诺里亚已通过晶体学表征为二乙醚溶剂化物,其氢核磁共振谱首次得到完全归属。之前推测但未报道的R3也通过晶体学表征为二甲基亚砜溶剂化物,这证实了它与诺里亚的不同连接方式。诺里亚和R3溶解度低,这排除了它们在II型PLs中的应用,然而,部分乙基化衍生物诺里亚-OEt溶解在尺寸排阻溶剂15-冠-5中,得到一种新的II型PL。这种PL对甲烷(CH)气体的吸收增强,支持了液体中存在空孔。详细的分子动力学模拟支持了液体中空孔的存在,并表明CH占据孔更有利。总体而言,这项工作修正了普遍接受的块状诺里亚样品的组成,并表明诺里亚衍生物适合合成更稳定的II型PLs。
