Ahmed N Mahfouz, Andrew Z Haddad, Jordan D Kocher, Akanksha K Menon
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引用次数: 0
Abstract
Thermally responsive ionic liquids (ILs) exhibit liquid-liquid phase separation when mixed with water and heated above a lower critical solution temperature (LCST), resulting in a water-rich (WR) and an IL-rich (ILR) phase. These binary IL-water mixtures can be employed in a variety of thermodynamic processes such as forward osmosis (FO) desalination, for which two solution properties are desirable: low phase separation temperature and high osmotic strength (osmolality). However, these two properties are interlinked, with ILs that exhibit higher osmotic strengths typically requiring higher phase separation temperatures. This behavior tends to arise from the hydrophilicity of the IL cations, which enhances osmotic strength while also elevating the phase separation temperature. In this work, we highlight a pathway to overcome this tradeoff by developing ternary IL mixtures (two ILs with varying cation hydrophilicity mixed with water), which lowers the phase separation temperature while maintaining and even enhancing the osmotic strength of the solution. We characterize the mixing behavior (osmolality, phase separation temperature, WR phase purity, and WR to ILR phase mass ratio) of four ILs as a function of their concentration in solution. We find that an enhancement of up to 81.6% in the osmolality with a concomitant reduction of up to 15.4% in the phase separation temperature can be achieved using this approach. The ternary mixture is also shown to improve the phase separation kinetics by nearly 95% compared to the binary mixture. Overall, this work highlights a new pathway to improve the performance of LCST ILs for water and energy applications.
热响应离子液体(ILs)与水混合并加热至较低的临界溶液温度(LCST)以上时,会出现液-液相分离,形成富水相(WR)和富离子液体相(ILR)。这些二元 IL 水混合物可用于各种热力学过程,例如正向渗透(FO)脱盐,其中有两种溶液特性是理想的:低相分离温度和高渗透强度(渗透压)。然而,这两种特性是相互关联的,渗透强度较高的 IL 通常需要较高的相分离温度。这种行为往往源于 IL 阳离子的亲水性,它在提高渗透强度的同时也提高了相分离温度。在这项工作中,我们强调了一种克服这种折衷的途径,即开发三元 IL 混合物(两种具有不同阳离子亲水性的 IL 与水混合),从而降低相分离温度,同时保持甚至增强溶液的渗透强度。我们将四种 IL 的混合行为(渗透压、相分离温度、WR 相纯度以及 WR 与 ILR 相质量比)表征为它们在溶液中浓度的函数。我们发现,使用这种方法可以提高渗透压达 81.6%,同时降低相分离温度达 15.4%。与二元混合物相比,三元混合物还能将相分离动力学提高近 95%。总之,这项研究成果为提高 LCST IL 在水和能源应用领域的性能开辟了一条新途径。
期刊介绍:
The Journal of Materials Chemistry A, B & C covers a wide range of high-quality studies in the field of materials chemistry, with each section focusing on specific applications of the materials studied. Journal of Materials Chemistry A emphasizes applications in energy and sustainability, including topics such as artificial photosynthesis, batteries, and fuel cells. Journal of Materials Chemistry B focuses on applications in biology and medicine, while Journal of Materials Chemistry C covers applications in optical, magnetic, and electronic devices. Example topic areas within the scope of Journal of Materials Chemistry A include catalysis, green/sustainable materials, sensors, and water treatment, among others.