Dependency of Anion and Chain Length of Imidazolium Based Ionic Liquid on Micellization of the Block Copolymer F127 in Aqueous Solution: An Experimental Deep Insight

Affordable CO2-derived alkyl carbamate ionic liquids boosting enzymatic production of renewable hydrocarbon fuels via Chlorella variabilis NC64A fatty acid photodecarboxylase (CVFAP)

The development of sustainable aviation fuel (SAF) presents a promising alternative to conventional jet fuel, with biofuels offering net-zero CO2 emissions. However, the conventional SAF production process typically involves expensive metal catalysts and extreme operating conditions. In contrast, the enzymatic approach offers a milder alternative; however, it is hindered by several limitations, including prolonged reaction times, reliance on cosolvents and low productivity. This study investigates the impact of CO2-based alkyl carbamate ionic liquids (ILs) on the enzymatic photodecarboxylation reaction catalyzed by Chlorella variabilis algal fatty acid photodecarboxylase (CvFAP). Notably, the study examines four ILs: N,N-dimethylammonium N',N'-dimethylcarbamate (DIMCARB), N,N-dipropylammonium N',N'-dipropylcarbamate (DPCARB), N,N-diallylammonium N',N'-diallylcarbamate (DACARB), and bis(2-ethylhexyl)-ammonium bis(2-ethylhexyl)carbamate (DBCARB). The results demonstrated that DACARB was the most optimal IL as it enhanced hydrocarbon conversion by 40 % and was able to reduce DMSO usage up to 86.7 % as compared to the absence of DACARB. This enhancement is attributed to DACARB's optimal balance of hydrophobic and hydrophilic properties, which increased enzyme activity while serving as a viable DMSO replacement, as well as acting as an allosteric modulator, as shown by Michaelis-Menten model fitting. Overall, this study highlights the potential of DACARB to facilitate process intensification in enzymatic SAF production, contributing to sustainable aviation practices.

Ionic Liquids Mediated Micellization of Pluronic Copolymers: Aggregation Behavior of Amphiphilic Triblock Copolymers

Understanding the micellization of amphiphilic triblock copolymers, especially Pluronics can play a persuasive role in engineering "smart" formulations for drug delivery applications. Their underlying self-assembly in the presence of designer solvents such as ionic liquids (ILs) provides combinatorial benefits of unique munificent properties of ILs and copolymers. The complex molecular interactions in the Pluronic copolymers/ILs mixed system influence the aggregation mechanism of copolymers depending on various aspects with no standardized factors to govern the structure-property relationship, which led to the practical applications. Here, we summarized recent progress in understanding the micellization process of IL-Pluronic mixed systems. Special emphasis was given to pure Pluronic systems (i.e., PEO-PPO-PEO) without any structural modifications, such as copolymerization with other functional groups, and ILs having cholinium and imidazolium groups. We expect that the correlation between existing/developing experimental and theoretical studies will provide the necessary basis and impetus for successful utilization in drug delivery applications.

Impact of Two Water-Miscible Ionic Liquids on the Temperature-Dependent Self-Assembly of the (EO)6-(PO)34-(EO)6 Block Copolymer

There are many studies on the self-assembly of triblock poly(ethylene oxide)-poly(propylene oxide)-poly(ethylene oxide) copolymers in aqueous solution. These polymers display a rich phase diagram as a function of block length, concentration, temperature, and additives. Here, we present a small-angle neutron scattering study of the impact of two water-miscible ionic liquids, 1-butyl-3-methylimidazolium chloride ([C₄C₁mim][Cl]) and 1-butyl-3-methylpyrrolidinium chloride ([C₄C₁pyrr][Cl]), on the temperature-dependent self-assembly of (EO)₆-(PO)₃₄-(EO)₆, also known as L62 Pluronic, in aqueous solution. Both ionic liquids depress the temperatures of the various structural transitions that take place, but ([C₄C₁pyrr][Cl]) has a stronger effect. The structures that the triblock copolymer self-assembles into do not dramatically change nor do they significantly change the series of structures that the system transitions through as a function of temperature relative to the various transition temperatures.

A magnetic porous organic polymer: catalytic application in the synthesis of hybrid pyridines with indole, triazole and sulfonamide moieties

Herein, the synthesis and characterization of a triazine-based magnetic ionic porous organic polymer are reported. The structure, morphology, and components of the prepared structure have been investigated with several spectroscopic and microscopic techniques such as FT-IR, EDX, elemental mapping, TGA/DTA, SEM, TEM, VSM, and BET analysis. Also, catalytic application of the prepared triazine-based magnetic ionic porous organic polymer was investigated for the synthesis of hybrid pyridine derivatives bearing indole, triazole and sulfonamide groups. Furthermore, the prepared hybrid pyridine systems were characterized by FT-IR, 1H NMR, 13C NMR and mass analysis. A cooperative vinylogous anomeric-based oxidation pathway was suggested for the synthesis of target molecules.

Effect of Pyrrolidinium Formate Ionic Liquid on Micellization of Direct and Reverse Pluronics in Aqueous Solutions

The behavior of direct and reverse Pluronic, copolymer nonionic surfactants, poly(ethylene oxide) PEO, and poly(propylene oxide) PPO copolymers, in aqueous solution and in the pyrrolidinium formate ([pyrr][F]) ionic liquid, was investigated using Fourier transform infrared spectroscopy (FTIR spectroscopy). The study was performed for a fixed Pluronic concentration at room temperature. We showed that in aqueous solution, the spectra associated with the direct and reverse Pluronics are similar irrespective of the difference in length of the various PPO and PEO blocks, their positions and the PPO:PEO ratio. The study of those same Pluronics dissolved in a pure pyrrolidinium formate solution showed that the Pluronic types were soluble and that the micellization process can take place at room temperature. The interaction between the Pluronic 10R5 aqueous solutions and the [pyrr][F] for various ionic liquid volumes is reported.