Department of Chemistry, Indian Institute of Technology, Kharagpur 721302, WB, India.
J Phys Chem B. 2013 Feb 7;117(5):1480-93. doi: 10.1021/jp310616p. Epub 2013 Jan 25.
A method developed for the first time, to create a huge number of ionic liquid (IL)-in-oil microemulsions has been discussed in our earlier publication (Rao, V. G.; Ghosh, S.; Ghatak, C.; Mandal, S.; Brahmachari, U.; Sarkar, N. J. Phys. Chem. B 2012, 116, 2850-2855). Here, we present facile methods to adjust the structural parameters of microemulsions using different ionic liquids (ILs) as additives (polar phase). We have characterized ILs/[C(4)mim][AOT]/benzene ternary system by performing a phase behavior study, dynamic light scattering (DLS) measurements, and (1)H NMR measurements. The IL loading capacity of microemulsions (area of single phase region) (i) increases with increase in alkyl chain length of cation of ILs and follows the trend [C(6)mim][TF(2)N] > [C(4)mim][TF(2)N] > [C(2)mim][TF(2)N], (ii) increases with decrease in cation anion interaction strength of added ILs and follows the trend [C(4)mim][TF(2)N] > [C(4)mim][PF(6)] > [C(4)mim][BF(4)]. So depending on the IL used, the amount of IL within the core of microemulsions can be easily manipulated to directly affect the size of aggregates in microemulsions. The size increase with increasing R value (R value is defined as the molar ratio of RTILs to [C(4)mim][AOT]) was found to be maximum in the case of [C(2)mim][TF(2)N]/[C(4)mim][AOT]/benzene microemulsions and follows the trend [C(2)mim][TF(2)N] > [C(4)mim][TF(2)N] > [C(6)mim][TF(2)N]. However, the size increase was almost the same with increase in R value in the case of ILs with different anions. The most promising fact about IL-in-oil microemulsions is their high thermal stability compared to that of aqueous microemulsions, so we investigated the effect of temperature on size of aggregates in microemulsions at R = 1.0. It is evident from dynamic light scattering measurements that the aggregates in microemulsions remain monodisperse in nature with increasing temperature, and in all the cases, the size of aggregates in microemulsions decreases with increasing temperature. The effect of water addition on IL-in-oil (IL/O) microemulsions was also studied in detail. By far, this is the first report where the effect of water addition on microemulsions containing hydrophobic ILs is being reported and compared with microemulsions containing hydrophilic ILs. We observed that the added water has a prominent effect on the microstructure of the microemulsions. In all the cases, (1)H NMR spectra provide more detailed information about intra/intermolecular interactions thus affording a clear picture of locations of (i) the RTILs in RTILs/[C(4)mim][AOT]/benzene microemulsions and (ii) the added water molecules in microemulsions.
一种新方法首次被开发用于创建大量的离子液体(IL)-油型微乳液,我们之前的出版物(Rao,V. G.;Ghosh,S.;Ghatak,C.;Mandal,S.;Brahmachari,U.;Sarkar,N. J. Phys. Chem. B 2012, 116, 2850-2855)中讨论过。在这里,我们提出了使用不同的离子液体(IL)作为添加剂(极性相)来调整微乳液结构参数的简便方法。我们通过进行相行为研究、动态光散射(DLS)测量和(1)H NMR 测量来表征 ILs/[C(4)mim][AOT]/苯三元体系。微乳液的 IL 负载能力(单相区域的面积)(i)随 IL 阳离子的烷基链长度的增加而增加,遵循[C(6)mim][TF(2)N]>[C(4)mim][TF(2)N]>[C(2)mim][TF(2)N]的趋势,(ii)随添加的 IL 的阳离子阴离子相互作用强度的降低而增加,遵循[C(4)mim][TF(2)N]>[C(4)mim][PF(6)]>[C(4)mim][BF(4)]的趋势。因此,根据使用的 IL,可以轻松地控制微乳液核心内的 IL 量,直接影响微乳液中聚集体的大小。发现随着 R 值(R 值定义为 RTILs 与[C(4)mim][AOT]的摩尔比)的增加,[C(2)mim][TF(2)N]/[C(4)mim][AOT]/苯微乳液的尺寸增加最大,遵循[C(2)mim][TF(2)N]>[C(4)mim][TF(2)N]>[C(6)mim][TF(2)N]的趋势。然而,在不同阴离子的 IL 情况下,随着 R 值的增加,尺寸增加几乎相同。与水基微乳液相比,IL-油型微乳液的一个最有前途的特点是其具有高热稳定性,因此我们在 R = 1.0 时研究了温度对微乳液中聚集体尺寸的影响。动态光散射测量表明,随着温度的升高,微乳液中的聚集体仍然保持单分散性,在所有情况下,微乳液中的聚集体尺寸随着温度的升高而减小。还详细研究了水的添加对 IL-油型(IL/O)微乳液的影响。到目前为止,这是第一个报道水的添加对含有疏水性 IL 的微乳液的影响并将其与含有亲水性 IL 的微乳液进行比较的报告。我们观察到添加的水对微乳液的微观结构有显著影响。在所有情况下,(1)H NMR 谱提供了关于分子内/分子间相互作用的更详细信息,从而清晰地描述了(i)RTILs 在 RTILs/[C(4)mim][AOT]/苯微乳液中的位置和(ii)微乳液中添加的水分子的位置。
