Noria and Its Derivatives As Hosts for Chemically and Thermally Robust Type II Porous Liquids

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2021 Nov 11

PMID 34760209

Citations 1

Authors

Francesca M Alexander

Sergio F Fonrouge

Jose L Borioni

Mario G Del Popolo

Peter N Horton

Simon J Coles

Benjamin P Hutchings

Deborah E Crawford

Stuart L James

Affiliations

Soon will be listed here.

Abstract

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.

Citing Articles

Water-Soluble Polyglycidol-Grafted Ladder Calix Resorcinarene Oligomers with Open Chain and Cyclic Topologies: Synthesis, Characteristics, and Biological Evaluation.

Penchev H, Dimitrov E, Novakov C, Haladjova E, Veleva R, Moskova-Doumanova V Polymers (Basel). 2024; 16(22).

PMID: 39599309 PMC: 11598056. DOI: 10.3390/polym16223219.

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