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Article

Probing Structures of Interfacial 1-Butyl-3-Methylimidazolium Trifluoromethanesulfonate Ionic Liquid on Nano-Aluminum Oxide Surfaces Using High-Pressure Infrared Spectroscopy

1
Department of Chemistry, National Dong Hwa University, Shoufeng, Hualien 974, Taiwan
2
Department of Natural Science, Northeastern State University, Tahlequah, OK 74464, USA
*
Author to whom correspondence should be addressed.
Appl. Sci. 2017, 7(8), 855; https://doi.org/10.3390/app7080855
Submission received: 20 July 2017 / Revised: 14 August 2017 / Accepted: 15 August 2017 / Published: 18 August 2017
(This article belongs to the Special Issue Optics and Spectroscopy for Fluid Characterization)

Abstract

:
The interactions between 1-butyl-3-methylimidazolium trifluoromethanesulfonate ([BMIM][TFS]) and nano-Al2O3 are studied using high-pressure infrared spectroscopy. The thickness of the [BMIM][TFS] interfacial layer on the aluminum oxide are adjusted by controlling the number of washes with ethanol. In contrast to the results obtained under ambient pressure, local structures of both the cations and anions of [BMIM][TFS] are disturbed under high pressures. For example, bands due to C-H stretching motions display remarkable blue-shifts in frequency as the pressure of the [BMIM][TFS]/Al2O3 composites is increased to 0.4 GPa. The bands then undergo mild shifts in frequency upon further compression. The discontinuous jump occurring around 0.4 GPa becomes less obvious when the amount of ionic liquid on the Al2O3 is reduced by washing with ethanol. The nano-Al2O3 with surfaces may weaken the cation/anion interactions in the interfacial area as a result of the formation of pressure-enhanced Al2O3/ionic liquid interactions under high pressures.

1. Introduction

Metal oxide nanoparticles possess different physicochemical properties in comparison to bulk materials, and the size of nanoparticles is responsible for the changes in their characteristics. Aluminum oxide, commonly called alumina, has tremendous applications in ceramics, medical products, and catalysis, to name a few [1,2,3,4,5,6]. Despite the expanding number of applications for aluminum oxide, the physical arrangement and interactions of liquids at Al2O3 surfaces remains poorly understood. Many experimental and theoretical studies have indicated the inherent complexity of interfacial interactions among certain liquid/Al2O3 mixtures, and the immobilization of liquids on Al2O3 surfaces may improve the applicability of these materials in industry [4,5,6].
Ionic liquids (ILs) are a subset of low-melting-point salts that are known for high ionic conductivities, low vapor pressures, and low flammability. This combination of properties has opened opportunities for ionic liquids to serve as alternatives for conventional volatile organic solvents [7,8,9,10]. Although ILs offer advantages over conventional solvents, there is still relatively little information available on the structures of ILs in the bulk and along various interfaces [7,9]. The most extensively studied ILs are 1-alkyl-3-methylimidazolium salts, which feature asymmetric cations [7,8,9,10]. The imidazolium ions are usually paired with anions that have highly delocalized charges or are intrinsically bulky. The liquid structures of 1-alkyl-3-methylimidazolium salts are strongly affected by the long-range charge organization of the constituent ions and may be described in terms of an extended quasi-lattice, in which ions are viewed as occupying sites in a disorganized crystalline lattice [11,12]. In this model, any particular ion may be viewed as being trapped within a “cage” that is defined by its nearest neighbors. For ILs, the immediate solvation shell of an ion is most likely to be populated with counterions. Thus, an ion will have frequent opportunities to form short-lived associated species (e.g., ionic pairs, clusters, or aggregates) with the ions composing its cage [7,13]. With three hydrogen atoms bound to the imidazolium ring, the most acidic proton (C2-H) may form cation/anion hydrogen bonds. The nonpolar alkyl side chain of the cation provides another source of mesoscopic self-assembly of imidazolium ILs into nanostructured polar/nonpolar domains. Such nano-segregation is frequently observed in small angle X-ray scattering experiments for alkyl side chains containing four or more carbon atoms [14]. Various studies demonstrate significant heterogeneities in certain ionic liquid dynamics, and much of the heterogeneity may arise from nano-structured associations with polar and nonpolar regions [7,8,9,10,13,14].
Microscopic structures of certain ILs at solid surfaces have received considerable attention in recent years [7,9,13]. Nevertheless, the interfacial interactions caused by ionic liquid adsorption on the surface of Al2O3 are complex and depend on the molecular structures of ILs. It has been suggested that Coulombic forces, hydrogen bonding, and π interactions may each play significant roles in defining the molecular ordering of ILs along the surface [7,9]. In this study, 1-butyl-3-methylimidazolium trifluoromethanesulfonate [BMIM][TFS] and nano-Al2O3 were chosen as a model IL and solid support, respectively. As pointed out by Andanson et al. [4], the TFS anion has many strong bands in the infrared spectrum. Unlike the bis(trifluoromethylsulfonyl)amide (NTf2) anion, the TFS anion has only one conformer, which simplifies the spectral analysis. Nano-Al2O3 was chosen in this study mainly due to the wide application of nano-Al2O3, particularly in the field of catalysis.
Vibrational spectroscopy is particularly useful in studying ionic liquid/Al2O3 interactions because the frequencies and intensities of cation and anion vibrational modes are sensitive to their immediate potential energy environments. In this way, changes in band frequencies and intensities may be used to infer changes in the local structures of the ions. Many spectroscopic studies on ionic liquid interactions with nanostructured metal oxides focus on changing the temperature of the composite or varying the molecular structure of the ionic liquid in contact with the solid (e.g., lengthening the alkyl side chain) to probe the interfacial interactions [1,2,3,4,5,6,7,8,9]. Hydrostatic pressure is another degree of freedom that can continuously tune the structures, interactions, and solvation of chemical systems. In the case of temperature changes, the sample’s properties can change significantly due to a simultaneous change in thermal energy and volume. However, the use of pressure as a variable allows one to separate the thermal and volume effects. Studies have shown the potential significance that pressure has on controlling the strength of intermolecular hydrogen bonding, especially the relatively weak C-H---X hydrogen bonds, where X is an anion atom [15,16,17,18]. Pressure-dependent changes in spectral features indicate that nanoparticles tend to influence local structures of certain ILs under high pressures. As certain ILs have been employed as graphene stabilizers, previous studies suggest that imidazolium ILs with short alkyl chain lengths (n < 4) may be suitable choices to modulate the performance of energy storage devices via pressure-enhanced interfacial interactions [15]. In order to obtain detailed insights into the ionic liquid/Al2O3 interactions, we use variable pressure as a window into the nature of hydrogen bonding structures of imidazolium ionic liquid/Al2O3 mixtures in this article.

2. Materials and Methods

Samples were prepared using 1-butyl-3-methylimidazolium trifluoromethanesulfonate ([BMIM][TFS], >95%, Fluka, Morris Plains, NJ, USA), and nanosized-aluminum oxide (nano-Al2O3, <50 nm, Aldrich, St. Louis, MO, USA). The nano-Al2O3 powders (ca. 0.006 g) were mixed with [BMIM][TFS] (ca. 0.06 g), followed by sonication for 30 min, centrifugation, several washes of the precipitate with ethanol (0.1 mL for a single wash), centrifugation, and drying under vacuum for 3 h. The infrared spectra of samples measured at ambient pressure were taken by filling samples in a cell characterized by two CaF2 windows without the spacers. A diamond anvil cell (DAC) of Merrill-Bassett design with a diamond culet size of 0.6 mm was used to generate pressures of up to ca. 2 GPa. Two type-IIa diamonds were used for mid-infrared measurements. Infrared (IR) spectra of the samples were measured on a Fourier transform spectrophotometer (Spectrum RXI, Perkin-Elmer, Naperville, IL, USA) equipped with an LITA (lithium tantalite) mid-infrared detector. The infrared beam was condensed through a 5× beam condenser onto the sample in the diamond anvil cell. To remove the absorption of the diamond anvils, the absorption spectra of the DAC were measured first and subtracted from those of the samples. Samples were contained in a 0.3-mm-diameter hole in a 0.25-mm-thick Inconel gasket mounted on the DAC. To reduce the absorbance of the samples, CaF2 crystals (prepared from a CaF2 optical window) were placed into the holes and compressed to be transparent prior to inserting the samples. A sample droplet filled the empty space of the entire hole of the gasket in the DAC, which was subsequently sealed when the opposing anvils were pushed toward one another. Typically, we chose a resolution of 4 cm1 (data point resolution of 2 cm1). For each spectrum, 1000 scans were compiled. Pressure calibration was performed following Wong’s method [19,20].

3. Results and Discussion

Figure 1 shows the infrared spectra of pure [BMIM][TFS], the [BMIM][TFS]/Al2O3 mixture, the mixture after two washes with ethanol, and the mixture after five washes obtained under ambient pressure. The amount of [BMIM][TFS] are adjusted by controlling the numbers of washes in this study; the amount of [BMIM][TFS] becomes almost depleted after five washes, as shown in Figure 1d. The IR spectrum of pure [BMIM][TFS] in Figure 1a shows two imidazolium C-H bands at 3116 and 3155 cm−1, a shoulder to the 3155 cm−1 band at 3098 cm−1, and three alkyl C-H bands at 2877, 2940, and 2967 cm−1, respectively [21]. As shown in Figure 1, no appreciable changes in spectral features and band frequencies of C-H vibrations occurred as [BMIM][TFS] was mixed with nano-Al2O3, except for a noticeable absorption caused by O-H groups from the surfaces of nano-Al2O3 that appears in Figure 1d. These results indicate that IR measurements recorded under ambient pressure may not be sensitive enough to monitor the interfacial interactions between the BMIM+ cation and nano-Al2O3.
Figure 2 displays the IR spectra of samples in the spectral range between 1000 and 1350 cm−1. This region of the spectrum is predominately dominated by absorption bands due to vibrations of the TFS anions. The bands at ca. 1165 and 1226 cm−1 are assigned to CF3 asymmetric and symmetric stretching vibrations, respectively. The absorption bands located near 1032 and 1270 cm−1 (doublet) are assigned to the symmetric and asymmetric stretching vibration of the SO3 group of the TFS anion, respectively. Comparing the spectral features of Figure 2d with those of Figure 2a reveal mild frequency shifts and narrowing for the bands at ca. 1165 and 1270 cm−1, caused by the presence of nano-Al2O3. The absorption of CaF2 windows (below 1050 cm−1) also becomes obvious in Figure 2d.
Figure 3 displays the IR spectra of a sample from a [BMIM][TFS]/Al2O3 mixture obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). The elevation of pressure to 0.4 GPa leads to a phase transition, and the imidazolium C-H bands are blue-shifted to 3102, 3132, and 3168 cm−1 in Figure 3b. The sharper structures of imidazolium C-H bands revealed in Figure 3b–g are in part due to the anisotropic environment in a solid structure. We note that spectral features of the [BMIM][TFS]/Al2O3 mixture in Figure 3 are almost identical to those of pure [BMIM][TFS], as revealed in our previous studies [21]. The results of Figure 3 indicate that the presence of nano-Al2O3 does not perturb ion/ion interactions from the perspective of the C-H stretching motions of the cations. Instead, the blue-shifts revealed in Figure 3 may originate from the combined effect of the overlap repulsion enhanced by hydrostatic pressure, C-H---O contacts, and so forth. The increased understanding of weak interactions, such as hydrogen bonding between the C-H groups on the imidazolium cation and oxygen atoms of the TFS anion, has required an expansion of the classical definition of hydrogen bonding. One of the intriguing aspects of C-H---O interactions is that the C-H bond tends to shorten as a result of the formation of blue-shifting hydrogen bonds. We demonstrate in Figure 3 that high pressure is a valuable method to probe pressure-enhanced blue-shifting of C-H hydrogen bonds in the [BMIM][TFS]/Al2O3 mixture. Scheiner’s group and Dannenberg’s group indicated that the origin of both red-shifting and blue-shifting hydrogen bonds may be the same, and suggested that both types of hydrogen bonds result from a combination of electrostatic, polarization, charge transfer, dispersion, and exchange/steric repulsion forces between proton donors and acceptors [22,23].
Figure 4 shows the infrared spectra of the [BMIM][TFS]/Al2O3 mixture attributed to the absorption of TFS anions under various pressures. As the mixture is compressed to 0.4 GPa in Figure 4b, the 1270 cm−1 (doublet) band narrowed and the band at 1165 cm−1 splits into two distinct bands at ca. 1152 and 1175 cm−1. These spectral changes may indicate a pressure-induced phase transition arising from both structural reorganization (due to ordered local structures) and a decrease in inhomogeneous broadening. The spectral features of the [BMIM][TFS]/Al2O3 mixture revealed in Figure 4 are almost identical to those of pure [BMIM][TFS]. In contrast to the bandwidth narrowing of asymmetric SO3 stretching vibration at ca. 1270 cm−1, the 1032 cm−1 band (symmetric SO3 stretching) displays anomalous bandwidth broadening upon compression in Figure 4b–g. It is likely that transverse optic (TO)-longitudinal optic (LO) splitting of the symmetric SO3 stretching band plays a non-negligible role in Figure 4 [11,12,24].
Figure 5 displays the IR spectra of a [BMIM][TFS]/Al2O3 mixture after five washes with ethanol obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). As shown in Figure 5a,b, no appreciable changes in the spectral features of C-H vibrations occur as the sample is compressed to 0.4 GPa. This result is remarkably different from that is revealed for the [BMIM][TFS]/Al2O3 mixture in Figure 3b. It appears that the presence of nano-Al2O3 has an influence on the supramolecular assemblies of the remaining ILs on the surface of Al2O3 after five washes and under high pressures, as revealed in Figure 5. The nano-Al2O3 surfaces may weaken the cation/anion interactions in the interfacial area as a result of the formation of enhanced ionic liquid/particle surface interactions under high pressures. The Al2O3/ionic liquid interactions may also affect the hydrogen-bonded network of interfacial [BMIM][TFS] under high pressures. In contrast to the results obtained under ambient pressure (Figure 1), the local structures of both the imidazolium C-H and alkyl C-H groups are disturbed under high pressures for the mixture after five washes, shown in Figure 5, when compared to the pressure dependence of the [BMIM][TFS]/Al2O3 mixture (Figure 3). Therefore, high pressures may have the potential to control the order and strength of ionic liquid/surface interactions in this system.
Figure 6 shows the infrared spectra of the mixture after five washes in the spectral range between 1000 and 1350 cm−1 obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). The absence of drastic band-narrowing and splitting in Figure 6 suggests that interfacial ionic liquid/Al2O3 interactions of the mixture after five washes may be enhanced by the application of pressure. As revealed in Figure 6g, the absorption bands display mild blue-shifts in frequency as the mixture is compressed to 2.5 GPa.
To illustrate the frequency shift, the pressure dependence of C-H stretching frequencies of the [BMIM][TFS]/Al2O3 mixture, the mixture after two washes with ethanol, and the mixture after five washes is plotted in Figure 7. The C-H bands corresponding to the [BMIM][TFS]/Al2O3 mixture display significant blue-shifts in frequency as the pressure increases to 0.4 GPa, and then undergo mild shifts in frequency when the pressure increases from 0.4 to 2.5 GPa. The discontinuous jump occurring around 0.4 GPa becomes less obvious for the mixture after two washes with ethanol. In Figure 7, we observe no discontinuous jump in frequency for the mixture after five washes. It is known that the hydrogen bond cooperativity due to concerted charge transfer can greatly enhance the strength of the individual hydrogen bonds involved in the coupling [25]. Hydrogen-bonding non-additivity and the size of clusters are suggested to be responsible for the enhancement of hydrogen bonding [25,26]. Thus, the anomalous jump in frequency at 0.4 GPa can be attributed to both the cooperative and geometric effects of blue-shifting hydrogen bonds. The disappearance of the discontinuous jump upon the reduction of ionic liquid through washing with ethanol may indicate the decrease in strength of blue-shifting hydrogen bonding as C-H/anion interactions are replaced by C-H/Al2O3 interactions. The loss of the frequency jump at 0.4 GPa due to washing is related to a reduction of the amount of ionic liquid along the interface. At thicker values, there is likely enough IL to form crystallites. If there is just a monolayer (or about that), crystallization might be difficult and hydrogen bond cooperativity may be reduced.
This study indicates that high pressures can serve as a useful tool to probe the strength of blue-shifting C-H hydrogen bonding in ILs deposited along the surface of nano-Al2O3 surfaces. Furthermore, the surfaces of Al2O3 appear to be capable of breaking or weakening the interactions of the cation/anion clusters, presumably in favor of stable ionic liquid/Al2O3 interactions under high pressures. Supplementary data (IR spectra of the mixture after two washes and pure [BMIM][TFS] with 99% purity) are included in Supplementary Materials (see Figures S1–S3).

4. Conclusions

In this study, we demonstrate that the effect of nano-Al2O3 on hydrogen bonding networks of [BMIM][TFS] can be probed by high-pressure infrared spectroscopy. There are no remarkable changes in the spectral features of [BMIM][TFS] in the presence of nano-Al2O3 at ambient pressure. Nevertheless, nano-Al2O3 may perturb the cation/anion aggregations as a result of the formation of pressure-enhanced ionic liquid/Al2O3 interactions when high pressure is applied to the composite materials. The relative strength of blue-shifting C-H hydrogen bonding, i.e., [BMIM][TFS] > [BMIM]-Al2O3, is also investigated by varying the applied pressure. This study indicates that high pressures may have the potential to tune the strength of ionic liquid/Al2O3 surface interactions. Moreover, high-pressure infrared spectroscopy provides an alternative avenue for a better understanding the interfacial properties of ILs in contact with nanostructured metal oxides.

Supplementary Materials

The following are available online at https://www.mdpi.com/2076-3417/7/8/855/s1, Figure S1: IR spectra of the mixture after two washes with ethanol obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g), Figure S2: Infrared spectra of the mixture after two washes with ethanol obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g), Figure S3: Infrared spectra of pure [BMIM][TFS] (99% , Lot: N00364.7, UniRegion) obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.3 GPa (curve g).

Acknowledgments

The authors thank the National Dong Hwa University and Ministry of Science and Technology (Contract No. MOST 106-2113-M-259-002) of Taiwan for financial support. The authors thank Yen-Hsu Chang and Min-Hsiu Shen for the assistance.

Author Contributions

Hai-Chou Chang is the idea source, writer of the manuscript, and provided data interpretation. Teng-Hui Wang contributed to FTIR spectra measurements. Christopher M. Burba is the co-writer and provided the idea of TO-LO splitting.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Infrared (IR) spectra of pure 1-butyl-3-methylimidazolium trifluoromethanesulfonate ([BMIM][TFS]) (curve a), the [BMIM][TFS]/Al2O3 mixture (curve b), the mixture after two washes with ethanol (curve c), and the mixture after five washes (curve d), recorded under ambient pressure. Curve d was baseline-corrected by subtracting a straight line. Relative intensities of the IR bands are given in increments of 0.05; the scale bar is displayed in the upper left corner of the figure.
Figure 1. Infrared (IR) spectra of pure 1-butyl-3-methylimidazolium trifluoromethanesulfonate ([BMIM][TFS]) (curve a), the [BMIM][TFS]/Al2O3 mixture (curve b), the mixture after two washes with ethanol (curve c), and the mixture after five washes (curve d), recorded under ambient pressure. Curve d was baseline-corrected by subtracting a straight line. Relative intensities of the IR bands are given in increments of 0.05; the scale bar is displayed in the upper left corner of the figure.
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Figure 2. IR spectra of pure [BMIM][TFS] (curve a), the [BMIM][TFS]/Al2O3 mixture (curve b), the mixture after two washes with ethanol (curve c), and the mixture after five washes (curve d), recorded under ambient pressure. Relative intensities of the IR bands are given in increments of 0.05; the scale bar is displayed in the upper left corner of the figure.
Figure 2. IR spectra of pure [BMIM][TFS] (curve a), the [BMIM][TFS]/Al2O3 mixture (curve b), the mixture after two washes with ethanol (curve c), and the mixture after five washes (curve d), recorded under ambient pressure. Relative intensities of the IR bands are given in increments of 0.05; the scale bar is displayed in the upper left corner of the figure.
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Figure 3. IR spectra of the [BMIM][TFS]/Al2O3 mixture obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). Relative intensities of the IR bands are given in increments of 0.1; the scale bar is displayed in the upper left corner of the figure.
Figure 3. IR spectra of the [BMIM][TFS]/Al2O3 mixture obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). Relative intensities of the IR bands are given in increments of 0.1; the scale bar is displayed in the upper left corner of the figure.
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Figure 4. IR spectra of the [BMIM][TFS]/Al2O3 mixture obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). Relative intensities of the IR bands are given in increments of 0.25; the scale bar is displayed in the upper left corner of the figure.
Figure 4. IR spectra of the [BMIM][TFS]/Al2O3 mixture obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). Relative intensities of the IR bands are given in increments of 0.25; the scale bar is displayed in the upper left corner of the figure.
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Figure 5. IR spectra of the mixture after five washes with ethanol obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). All curves were baseline-corrected by subtracting straight lines. Relative intensities of the IR bands are given in increments of 0.05; the scale bar is displayed in the upper left corner of the figure.
Figure 5. IR spectra of the mixture after five washes with ethanol obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). All curves were baseline-corrected by subtracting straight lines. Relative intensities of the IR bands are given in increments of 0.05; the scale bar is displayed in the upper left corner of the figure.
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Figure 6. IR spectra of the mixture after five washes with ethanol obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). Relative intensities of the IR bands are given in increments of 0.2; the scale bar is displayed in the upper left corner of the figure.
Figure 6. IR spectra of the mixture after five washes with ethanol obtained under ambient pressure (curve a) and at 0.4 (curve b), 0.7 (curve c), 1.1 (curve d), 1.5 (curve e), 1.8 (curve f), and 2.5 GPa (curve g). Relative intensities of the IR bands are given in increments of 0.2; the scale bar is displayed in the upper left corner of the figure.
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Figure 7. Pressure dependence of the C-H stretching frequencies of the [BMIM][TFS]/Al2O3 mixture (diamonds), the mixture after two washes with ethanol (squares), and the mixture after five washes (triangles).
Figure 7. Pressure dependence of the C-H stretching frequencies of the [BMIM][TFS]/Al2O3 mixture (diamonds), the mixture after two washes with ethanol (squares), and the mixture after five washes (triangles).
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MDPI and ACS Style

Chang, H.-C.; Wang, T.-H.; Burba, C.M. Probing Structures of Interfacial 1-Butyl-3-Methylimidazolium Trifluoromethanesulfonate Ionic Liquid on Nano-Aluminum Oxide Surfaces Using High-Pressure Infrared Spectroscopy. Appl. Sci. 2017, 7, 855. https://doi.org/10.3390/app7080855

AMA Style

Chang H-C, Wang T-H, Burba CM. Probing Structures of Interfacial 1-Butyl-3-Methylimidazolium Trifluoromethanesulfonate Ionic Liquid on Nano-Aluminum Oxide Surfaces Using High-Pressure Infrared Spectroscopy. Applied Sciences. 2017; 7(8):855. https://doi.org/10.3390/app7080855

Chicago/Turabian Style

Chang, Hai-Chou, Teng-Hui Wang, and Christopher M. Burba. 2017. "Probing Structures of Interfacial 1-Butyl-3-Methylimidazolium Trifluoromethanesulfonate Ionic Liquid on Nano-Aluminum Oxide Surfaces Using High-Pressure Infrared Spectroscopy" Applied Sciences 7, no. 8: 855. https://doi.org/10.3390/app7080855

APA Style

Chang, H. -C., Wang, T. -H., & Burba, C. M. (2017). Probing Structures of Interfacial 1-Butyl-3-Methylimidazolium Trifluoromethanesulfonate Ionic Liquid on Nano-Aluminum Oxide Surfaces Using High-Pressure Infrared Spectroscopy. Applied Sciences, 7(8), 855. https://doi.org/10.3390/app7080855

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