Imidazolium-based Ionic Liquids Research Articles

2D Raman-THz spectroscopy of imidazolium-based ionic liquids.

An investigation of the low-frequency (i.e., less than 5THz), inter-molecular dynamics of three imidazolium-based ionic liquids-1-butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([C4mim][NTf2]), 1-butyl-3-methylimidazolium dicyanamide ([C4mim][DCA]), and 1-ethyl-3-methylimidazolium dicyanamide ([C2mim][DCA])-is presented using two-dimensional (2D) Raman-THz spectroscopy combined with molecular dynamics (MD) simulations. By observing an echo in the 2D Raman-THz response, the experimental results indicate that the substitution of a small [DCA]- anion with a larger [NTf2]- one leads to a substantial increase in the structural inhomogeneity of the low-frequency modes of the system. These findings are corroborated by MD simulations, comparing the experimentally observed echo decay times to those of a computed velocity echo. The comparison suggests that the echo decay time reflects the instantaneous amount of structural order related to the charge alternation network, which is enhanced for the ionic liquid with the larger anion.

Imidazolium-Based Ionic Liquid Exhibiting Dual Hydrophilic and Oleophobic Properties without Polar End Groups.

Simultaneously hydrophilic and oleophobic surfaces offer substantial advantages for applications such as antifogging, self-cleaning, and oil-water separation. It remains challenging to engineer such surfaces without requiring polar functional groups. This study introduces HFIL, a novel ionic liquid (IL) coating that achieves simultaneous hydrophilic and oleophobic properties via a one-step dip-coating process without relying on polar functional groups. Key findings show that, despite the bulk form of HFIL having a high hexadecane contact angle (HCA) of 74.1° and an even higher water contact angle (WCA) of 87.6°, the IL forms a stable monolayer on high-energy surfaces exhibiting a much lower WCA of approximately 40° with minimal change to the HCA. Washing tests demonstrate that, even without the polar functional groups, there is a non-zero bonded thickness upon which the oleophobicity is comparable to polytetrafluorethylene (PTFE). These properties highlight HFIL's potential for durable applications in antifouling, antifogging, and environmental separation technologies, where selective liquid interactions are essential. This work contributes to a broader understanding of IL-based surface modifications, advancing the development of high-performance coatings.

Single Particle Dynamics at the Free Surface of Imidazolium-Based Ionic Liquids.

In this work, we carry out a systematic computer simulation investigation of the single particle dynamics at the free surface of imidazolium-based room temperature ionic liquids by applying intrinsic surface analysis. Besides assessing the effect of the potential model and temperature, we focus in particular on the effect of changing the anion type, and, hence, their shape and size. Further, we also address the role of the length of the cation alkyl chains, known to protrude into the vapor phase, on the surface dynamics of the ions. We observe that the surface dynamics of ionic liquids, being dominated by strong electrostatic interactions, is about 2 orders of magnitude slower than that for common molecular liquids. Furthermore, the free energy driving force for exposing apolar chains to the vapor phase "pins" the cations at the surface layer for much longer than anions, allowing them to perform noticeable lateral diffusion at the liquid surface during their stay there. On the other hand, anions, accumulated in the second layer beneath the liquid surface, stay considerably longer here than in the surface layer. The ratio of the mean surface residence time of the cations and anions depends on the relative size of the two ions: larger size asymmetry typically corresponds to larger values of this ratio. We also find, in a clear contrast with the bulk liquid phase behavior, that anions typically diffuse faster at the liquid surface than cations. Finally, our results show that the surface dynamics of the ions is largely determined by the apolar layer of the cation alkyl chains at the liquid surface, as in the absence of such a layer, cations and anions are found to behave similarly with respect to their single particle dynamics.

A Comprehensive Review of the Thermophysical Properties of Energetic Ionic Liquids

Energetic ionic liquids (EILs) have various industrial applications because they release chemically stored energy under certain conditions. They can avoid some environmental problems caused by traditionally used toxic fuels. EILs, which are environmentally friendly and safer, are emerging as an alternative source for hypergolic bipropellant fuels. This review focuses on the crucial thermophysical properties of the EILs. The properties of imidazolium and triazolium-based ionic liquids (ILs) are discussed here. The thermophysical properties addressed, such as glass transition temperature, viscosity, and thermal stability, are critical for designing EILs to meet the need for sustainable energy solutions. Imidazolium-based ILs have tunable physical properties making them ideal for use in energy storage while triazolium-based ILs have thermal stability and energetic potential. As a result, it is important to understand and compile thermophysical properties so they can help researchers synthesize tailored compounds with desirable characteristics, advancing their application in energy storage and propulsion technologies.

Acid-functionalized PVA composite membranes for pervaporation-assisted esterification.

Composite flat-sheet membranes functionalized with imidazolium-based ionic liquids (ILs) grafted to poly(vinyl alcohol)/glutaraldehyde as a catalytic layer were developed to enhance the esterification between n-butanol and acetic acid. The functionalized membranes were produced via dip-coating commercial pervaporation membranes, and two distinct Brønsted-acidic ILs with an imidazolium-based cation and different (hydrogen sulfate [HSO4]- or bromide [Br]-) anions were compared. Compact, 12 μm-thick, defect-free catalytic layers were observed on top of the pervaporation membrane supports, and the determined penetration depth of the ILs confirmed their presence in the upper part of the coating. While both ILs could significantly promote the esterification of n-butanol and acetic acid, the [HSO4]- anion catalyzed the formation of butyl acetate more effectively than [Br]--based species, resulting in yields of up to 50% over 15 h. Furthermore, the coated membranes exhibited enhanced water separation factors compared to the unfunctionalized one owing to the reduced swelling of the coated membranes accompanied with their diminished wettability.

Thermodynamic properties and corrosivity of water+ imidazolium-based ionic liquids as new working pairs for absorption heat transformer cycle

Thermodynamic properties and corrosivity of water+ imidazolium-based ionic liquids as new working pairs for absorption heat transformer cycle

Imidazolium-based and pyridinium-based ionic liquids for methyl chloroacetate absorption

Imidazolium-based and pyridinium-based ionic liquids for methyl chloroacetate absorption

The surface activity exploration of novel trisubstituted imidazolium-based ionic liquids surfactants with hexanoic acid chain

The surface activity exploration of novel trisubstituted imidazolium-based ionic liquids surfactants with hexanoic acid chain

Insights into the electrochemical degradation mechanisms of imidazolium-based ionic liquids in the aqueous solution

Insights into the electrochemical degradation mechanisms of imidazolium-based ionic liquids in the aqueous solution

Short alkyl-chained Imidazolium-based Ionic Liquids: Promising green solution or potential environmental threat?

Ionic Liquids (ILs) are currently applied in a wide variety of fields, with promising outcomes in microalgae high value biocompounds extraction. The occurrence of these compounds in natural water systems, with their characteristic stability and low biodegradability, becomes a threat worthy of attention. In the present study, Dunaliella tertiolecta, Isochrysis galbana and Rhinomonas reticulata were exposed to 1-butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([BMIM] Tf2N) for 72, 168 and 264h, at 20 and 25°C. Obtained results suggest that the N-containing cationic ring in the selected IL could act as a nitrogen source, aiding protein synthesis and growth in the three studied microalgae. Moreover, this specific IL might become a potential eutrophication agent when discharged in aquatic ecosystems, already pressured by climate change conditions. Important lipid contents, mainly in I. galbana and associated with increased cellular energy allocation values, could be related to mitochondrial stress, which is known to be a lipid accumulation promoting factor. Hence, we hypothesise that, since [BMIM] Tf2N does not appear to impair growth or biocompound accumulation, it could be a candidate for microalgae biomass pretreatment in biodiesel production. However, its life cycle and disposal must be carefully considered.

Ultrathin Films of a Nitrile-Functionalized Ionic Liquid [C3CNC1Im][Tf2N] on Au(111) and Pt(111): Adsorption, Growth, and Thermal Behavior.

We studied the adsorption and thermal behavior of the nitrile-functionalized ionic liquid (IL) [C3CNC1Im][Tf2N] on Au(111) and Pt(111) between 150 and 600 K. Ultrathin films were prepared at 150 K by physical vapor deposition (PVD) and were characterized by angle resolved X-ray photoelectron spectroscopy (ARXPS). At 150 K, the IL adsorbs intact with a similar orientation on both surfaces: In the first layer, the so-called wetting layer, the cation lies flat on the surface and the anion is bound in cis-configuration with the SO2 groups toward the surface and the CF3 groups away from the surface. On Au(111), subsequent deposition of IL in the multilayer regime at 150 K shows 2D growth up until ∼0.75 ML and a transition to moderate 3D at higher coverages. Temperature-programmed XPS indicates a change in surface morphology toward more pronounced 3D islands for the multilayers on top of the wetting layer between 220 and 290 K. From 350 to 440 K, desorption of multilayers occurs, with IL decomposition starting at 375-400 K. On the more reactive Pt(111) surface, decomposition starts already above 280 K. Notably, this temperature is ∼80 K higher than the onset for decomposition of related nonfunctionalized imidazolium-based ILs, that is, [C2C1Im][OTf], [C1C1Im][Tf2N], and [C8C1Im][Tf2N] on Pt(111). This difference is attributed to the nitrile functionality. Our findings demonstrate that functionalizing ILs significantly modifies their thermal properties, which is of high relevance for SCILL (solid catalyst with an ionic liquid layer) systems.

Polymerizable Ionic Liquid-Based Gel Polymer Electrolytes Enabled by High-Energy Electron Beam for High-Performance Lithium-Ion Batteries.

Polymerizable ionic liquid-based gel polymer electrolytes (PIL-GPEs) were developed for the first time using high-energy electron beam irradiation for high-performance lithium-ion batteries (LIBs). By incorporating an imidazolium-based ionic liquid (PIL) into the polymer network, PIL-GPEs achieved high ionic conductivity (1.90 mS cm-1 at 25 °C), a lithium transference number of 0.62, and an electrochemical stability exceeding 5 V. E-beam irradiation enabled rapid polymer network formation within a metal-cased battery structure, eliminating the need for initiators and improving the process efficiency. In the NCM811/PIL-GPE/Li cells, PIL-GPE (8:2) delivered an initial discharge capacity of 198.8 mAh g-1 with 82% retention at 100 cycles, demonstrating enhanced thermal stability and cycling performance compared to traditional GPEs. The demonstrated PIL-GPEs demonstrate strong potential for high-stability, high-performance LIB applications.

Asymmetric Imidazolium-Based Ionic Liquid Crystal with Enhanced Ionic Conductivity in Low-Temperature Smectic Phases

We report the synthesis and characterization of a novel asymmetric imidazolium-based ionic liquid crystal (ILC) dimer exhibiting stable smectic phases over a wide temperature range, including room temperature. This unique molecular structure, combining two distinct mesogenic cores, reduces packing density, which enhances ion mobility and achieves high ionic conductivity in the smectic phase (0.1 mS cm−1 at 40 °C). Electrochemical impedance spectroscopy (EIS) confirmed improved ionic conductivity at lower temperatures, along with a stable electrochemical window of ±3 V. Application as a solid-state electrolyte in an electrochromic device demonstrated effective switching behavior and reversible redox cycles. These findings suggest that this asymmetric imidazolium-based ILC is a viable candidate for advanced electrochemical applications due to its structural stability and anisotropic ionic pathways.

Ionic liquid coating for stir bar sorptive extraction and its application for extraction and nontargeted screening analysis via TD-GC-Orbitrap-HRMS of pollutants in river water.

In this study, a novel imidazolium-based ionic liquid (IL) coating was developed for stir bar sorptive extraction (SBSE) using a sol-gel method. The effects of different counterions, conditioning temperatures and polymer compositions were investigated. The stir bar with bis((trifluoromethyl)sulfonyl) amide 1-butyl-3-(3-(triethoxysilyl)propyl)-1H-imidazol-3-ium showed good mechanical and thermal stability with high resistance to water solubilization. The extraction efficiency of the IL-coated stir bar was evaluated on a mixture of 11 compounds presenting a wide range of polarities (log Ko/w values between 0.65 and 7.21) using thermodesorption gas chromatography coupled with Orbitrap high-resolution mass spectrometry (TD-GC-Orbitrap-HRMS). The results showed that extraction yields were increased for the IL-stir bar. In contrast, the commercial polydimethylsiloxane (PDMS) stir bar resulted in decreased yields with salt addition, particularly for compounds with log Ko/w > 4. SBSE of contaminants was performed on natural waters collected from France, followed by nontargeted analysis using TD-GC-Orbitrap-HRMS. The results revealed the detection of over 1,000 compounds, with 334 compounds annotated after deconvolution. The IL-stir bar with the addition of NaCl specifically extracted five times more compounds (167 compounds) than did the commercial PDMS stir bar (29 compounds) and more than 10 times more with the addition of NaCl with the PDMS stir bar (15 compounds). Various pollutants, including pesticides, personal care products, polychlorinated biphenyls (PCBs) and polycyclic aromatic hydrocarbons (PAHs), were identified. The annotations of the identified compounds were classified according to a level of confidence based on comparisons of retention indices, match library spectra and high-resolution mass filters.

Rapid and Accurate Prediction of the Melting Point for Imidazolium-Based Ionic Liquids by Artificial Neural Network

Rapid and Accurate Prediction of the Melting Point for Imidazolium-Based Ionic Liquids by Artificial Neural Network

Imidazolium-Based Ionic Liquid Electrolytes for Fluoride Ion Batteries.

The fluoride-ion battery (FIB) is a post-lithium anionic battery that utilizes the fluoride-ion shuttle, achieving high theoretical energy densities of up to 1393 Wh L-1 without relying on critical minerals. However, developing liquid electrolytes for FIBs has proven arduous due to the low solubility of fluoride salts and the chemical reactivity of the fluoride ion. By introducing a chemically stable electrolyte based on 1,3-dimethylimidazolium [MMIm] bis(trifluoromethanesulfonyl)imide [TFSI] and tetramethylammonium fluoride (TMAF), we achieve an electrochemical stability window (ESW) of 4.65 V, ionic conductivity of 9.53 mS cm -1, and a solubility of 0.67 m. The origin of this high solubility and the solvation structure were investigated using NMR spectroscopy and neutron total scattering, showing a fluoride solvation driven by strong electrostatic interactions and weak hydrogen bonding without covalent H-F character. This indicates the chemical stability of 1,3-dimethylimidazolium toward the fluoride ion and its potential as an electrolyte for high-voltage FIBs.

Surface-Enhanced Electronic and Vibrational Raman Spectroscopy of Ionic Liquid [BMI][PF6] on Au Electrode

Room-temperature ionic liquids have gathered great attention across various fields in recent years due to their fascinating physical and chemical properties. These liquids are, for example, expected as a next-generation solvent-free electrolyte. Their structure and dynamics at an electrode interface, where an electrical double layer is formed, should differ from those for conventional dilute electrolyte solutions. Because the performance of ionic liquids as electrolytes is significantly influenced by their behavior in the electrical double layer, many vibrational spectroscopic studies have been conducted to understand their properties at the molecular level. However, the interpretation of vibrational spectrum often suffers from its complicated spectral features. In this study, we observed not only the interfacial structure of ionic liquid on Au electrode but also the surface charge density of Au electrode at the same time using surface-enhanced electronic and vibrational Raman scattering (SERS) spectroscopy in a wide frequency range between 10 and over 2000 cm-1, which can provide a complete picture of the electrical double layer at the ionic liquid/Au interface.In this study, an imidazolium-based ionic liquid, 1-n-butyl-3-methylimidazoium hexafluorophosphate [BMI][PF6], with a residual water concentration below 5 ppm was used as an electrolyte. A SERS-active Au electrode was prepared by drop-casting a colloidal solution of Au nanoparticles with an average diameter of 100 nm onto the surface of a smooth Au electrode, followed by an electrochemical surface cleaning and vacuum-drying at 120°C for 1 hour. Then, the SERS-active Au electrode and the ionic liquid were sealed in a homemade three-electrode electrochemical Raman cell in an Ar-filled glovebox where H2O were below 0.1 ppm. Prior to SERS measurement, oxidation-reduction cycles were applied within the electrochemical potential window of [BMI][PF6] for further cleaning of the Au electrode surface. SERS spectra were measured with a 632.8 nm He-Ne laser under applied potential. The measured spectra were converted to the SERS susceptibility (χ”SERS) spectra using a conversion method described in previous reports1,2.Fig. 1 shows a typical SERS spectrum of [BMI][PF6] on Au electrode at open circuit potential, which includes both vibrational sharp peaks (vibrational SERS, vSERS) and a broad electronic background continuum (electronic SERS, eSERS). The observed peaks in the range of 1000 cm-1 to 1600 cm-1 are assigned to vibrational modes of BMI cation. The peak at 740 cm-1 is attributed to the symmetric stretching of PF6 anion. There is also a peak at around 180 cm-1, which can be assigned to the external mode of PF6 anion adsorbed on Au. In the THz region (10 cm-1 to 100 cm-1), there exists a broad feature, which is related to anion-cation interactions. When the applied potential was scanned to the negative direction, significant spectral changes were observed in both vSERS peaks and the eSERS background, which can be interpreted as desorption of PF6 anion, replacement of cation/anion layering structures, increase in the surface charge on Au, etc. These changes were in good agreement in capacitive current responses observed in the cyclic voltammogram.Reference(1) M. Inagaki, T. Isogai, K. Motobayashi, K. -Q. Lin, B. Ren, K. Ikeda, Chem. Sci., 11, 9807 (2020)(2) R. Kamimura, T. Kondo, K. Motobayashi, K. Ikeda, Phys. Status Solidi B, 259, 9, 2100589 (2022) Figure 1

Improved Thermal Stability of Ionic Liquid through Hydrogen Bond Donor As an Electrolyte for Fluoride-Ion Battery

Fluoride ion batteries (FIBs) have recently gained much attention as a next generation battery system because of their potential to surpass lithium-ion batteries (LIBs) in many aspects such as high energy density and low cost. FIBs with solid or liquid electrolyte have been studied intensively, amongst liquid-based FIBs has an advantage of good interfacial contact between the electrolyte and electrode, and low-temperature operation over all-solid-state FIBs. However, stability has been a major concern for liquid electrolytes. The instability caused by the strong basicity of F− ion attacking most of the commonly used organic solvents leading to side reactions.1 So far bis(2,2,2-trifluoroethyl) ether (BTFE), which has good base resistance, has been proposed as an effective organic solvent for electrolyte.2 However, the boiling point of BTFE is relatively low (64 °C). While looking beyond organic solvents, ionic liquids (ILs) can be a choice as an electrolyte for FIBs owing to their good properties such as nonvolatility and wide electrochemical window.3 It is commonly known that quaternary ammonium cations undergo Hofmann elimination, during which β-hydrogen is withdrawn by strong bases such as OH− and F− ions.4,5 Therefore, to use ILs as an electrolyte for FIB, it is necessary to improve their stability against F− ion. One way to weaken the basicity of F- ion is to solvate them by a complexing agent. Hagiwara et al. reported that imidazolium-based ILs containing ethylene glycol are stable despite the presence of F− ion.6 Bond formation between F− ion and hydrogen in the hydroxy groups of ethylene glycol and imidazolium-based cation prevents the F− ion from attacking the β-hydrogen of the cation's alkyl chain. However, there have been no reports of FIBs using ILs containing solvated F− ion as electrolytes. In this study, we investigated the thermal stability of choline bis(trifluoromethanesulfonyl)amide (N111(2OH) TFSA), an IL with hydrogen bond donor functional group, against F− ions. Furthermore, we performed charge-discharge tests on liquid-based FIBs using N111(2OH) TFSA containing fluoride salt as an electrolyte.N111(2OH) TFSA (Fig. 1 (a)) was synthesized by ion exchange of N111(2OH) Cl with K TFSA. The melting point of the synthesized N111(2OH) TFSA was estimated to be 38 °C from DSC measurement and it was solid at room temperature. 0.4 mol kg−1 tetramethylammonium fluoride (TMAF) in N111(2OH) TFSA was found to be stable up to about 150 °C (Fig. 1(c)). TGA measurements of N,N,N-trimethyl-N-propylammonium (N1113 TFSA) (Fig. 1(b)) without hydroxy groups were also performed under the same conditions for comparison. A solution of 0.4 mol kg−1 TMAF in N1113 TFSA showed a gradual weight loss right after the measurement was started, with a significant weight loss at about 120 °C (Fig. 1(c)). These results suggest that N111(2OH) TFSA with the hydroxy group exhibits higher thermal stability toward F− ion. This was attributed to the hydrogen bonding of the hydroxy group to F− ion, which weakened the basicity of F− ion. Finally, charge-discharge tests were performed in a three-electrode cell using BiF3 working electrode, Pb counter electrode, and Ag/Ag+ reference electrode. Figure 1 (d) shows charge-discharge curves of BiF3 electrode with 0.4 mol kg−1 TMAF in N111(2OH) TFSA as an electrolyte at 60 °C. The first discharge capacity of the BiF3 electrode was 300 mAh g−1, which represents 99 % of the theoretical capacity of BiF3 (302 mAh g−1) with a columbic efficiency of 85%. This result suggests that the BiF3 was reversibly defluorinated/fluorinated with 0.4 mol kg−1 TMAF in N111(2OH) TFSA.AcknowledgmentThis presentation is based on results obtained from a project, JPNP21006, commissioned by the New Energy and Industrial Technology Development Organization (NEDO).References(1) V. K. Davis, et al., Mater. Chem. Front., 2019, 3, 2721-2727.(2) V. K. Davis, et al., Science, 2018, 362, 1144–1148.(3) K. Okazaki, et al., ACS Energy Lett., 2017, 2, 1460–1464(4) S. Raiguel, et al., Green Chem., 2020, 22, 5225-5252.(5) H. Sun, and S. G. Dimagno, J. Am. Chem. Soc., 2005, 127, 2050-2051.(6) Z. Chen, et al., J. Phys. Chem. Lett., 2018, 9, 6662−6667 Figure 1

Machine-Learning Assisted Analysis on the Transport Behavior of Zn2+ in Room-Temperature Ionic Liquid Electrolytes

Imidazolium-based room-temperature ionic liquids (RTILs) show promise as electrolytes for zinc-air batteries due to their chemical stability and high ionic conductivity. While experimental performance data for various RTILs exist, the atomistic mechanisms underlying ion transport phenomena remain understudied, primarily due to computational costs and force field development challenges. This study presents a machine learning interatomic potential (MLIP) for imidazolium-based RTILs with four anion species: BF4, PF6, bis(trifluoromethanesulfonyl)imide (TFSI), and trifluoromethanesulfonate (TfO). We fine-tuned the pretrained MACE-MP-0 model using a dataset of 100 distinct configurations sampled from molecular dynamics (MD) trajectories of randomly generated RTIL mixtures. The MD simulations for data generation were performed using MACE-MP-0 potential to accelerate configurational sampling. The resulting MLIP demonstrates excellent generalization to out-of-domain data and accurately predicts RTIL densities. Using the trained MLIP, we performed 300 ps NVT MD simulations for each anion type. Radial distribution function analysis reveals that the primary solvation shell of Zn2+ consists of RTIL anions, which implies Zn2+-anion correlations in Zn2+ ion transport. Further investigation suggests a linear relationship between logarithmic ionic conductivity and Zn2+-cation binding energy, providing insights into the underlying transport mechanisms in these RTIL electrolytes.

Binary Mixture–Based Electrolytes Using Imidazolium-Based Ionic Liquids for Enhanced Safety and Electrochemical Performance of Lithium-Ion Batteries

In recent years, secondary lithium-ion batteries (LIBs) have become critical components for portable devices and large power source systems such as electric vehicles (EVs) and hybrid EVs (HEVs).[1],[2] However, conventional LIBs typically use flammable nonaqueous liquid electrolytes, posing a serious safety risk. Our previous study[3] demonstrated that one promising approach for safe LIBs involves using electrolytes based on a series of ionic liquids (ILs) with branched alkyl imidazolium cations. The introduction of bulky branched alkyl groups enhances charge delocalization in imidazolium cations, thereby improving the electrochemical reduction stability. Herein, we evaluated the compatibility and electrochemical performance of two types of ILs: branched alkyl functional and electrochemically polymerizable ILs. Moreover, binary mixture–based electrolytes based on their ILs were investigated for use in LIBs.We synthesized two types of ILs: reduction-stable and polymerizable ILs (Fig. 1). An IL-based electrolyte was mixed with various compositions of reduction-stable and polymerizable ILs, with LiFSA (LiFSA molal concentration: ca. 1.5 mol/kg) serving as the Li ion source. The characteristics of the involved battery were examined using a graphite electrode | IL–LiFSA mixture–based electrolyte | Li metal half-cell configuration. The graphite electrode sheets comprised NMC powder (86 wt%) as the active material, acetylene black (7 wt%) as an electrically conductive additive, and poly(vinylidene fluoride) (7 wt%) as a binder. The graphite electrode sheet, separator, IL–LiFSA mixture–based electrolyte, and Li were assembled into a battery cell. Performance tests for charge–discharge rates were conducted at 303 K, with the involved rates varying from 0.1 to 0.5 C.Fig. 2 shows the first charge–discharge profiles of the graphite | Li half-cells with [EPisoIm][FSA]–, [APisoIm][FSA]–, and [EPisoIm]0.8[APisoIm]0.2[FSA]–based electrolytes. During the first charge with the [APisoIm][FSA]– and [EPisoIm]0.8[APisoIm]0.2[FSA]–based electrolytes, a plateau was observed at approximately 0.5 V, attributed to the reduction decomposition and polymerization of [APisoIm] cations on graphite. The presence of [APisoIm] cations enabled the formation of a stable solid electrolyte interface, an electron-insulating, lithium-ion-conducting film.[1] M. Wakihara, “Recent developments in lithium ion batteries”, Mater. Sci. Eng., R, 33, 109 (2001).[2] D. D. Lecce, R. Verrelli, and J. Hassoun, “Lithium-ion batteries for sustainable energy storage: recent advances towards new cell configurations”, Green Chem., 19, 3442 (2017). Figure 1