Ionic Liquids as Working Fluids for Heat Storage Applications: Decomposition Behavior of N-Butyl-N-methylpyrrolidinium tris(pentafluoroethyl)trifluorophosphate

Ionic liquids (ILs) represent promising working fluids to be used in thermal energy storage (TES) technologies thanks to their peculiar properties, such as low volatility, high chemical stability, and high heat capacity. Here, we studied the thermal stability of the IL N-butyl-N-methylpyrrolidinium tris(pentafluoroethyl)trifluorophosphate ([BmPyrr]FAP), a potential working fluid for TES applications. The IL was heated at 200 °C for up to 168 h either in the absence or in contact with steel, copper, and brass plates to simulate the conditions used in TES plants. High-resolution magic angle spinning nuclear magnetic resonance spectroscopy was found to be useful for the identification of the degradation products of both the cation and the anion, thanks to the acquisition of 1H, 13C, 31P, and 19F-based experiments. In addition, elemental analysis was performed on the thermally degraded samples by inductively coupled plasma optical emission spectroscopy and energy dispersive X-ray spectroscopy. Our analysis shows a significant degradation of the FAP anion upon heating for more than 4 h, even in the absence of the metal/alloy plates; on the other hand, the [BmPyrr] cation displays a remarkable stability also when heated in contact with steel and brass.


Introduction
Development of new generation thermal energy storage (TES) technologies is a factor of primary importance for efficient use of solar thermal energy as well as industrial waste or process heat [1]. TES efficiency noticeably depends on the thermo-physical properties of the working heat storage material, which has to offer high performance in terms of storage capacity and stability under required operating conditions [2]. In case of solar concentrating power plants, water, diathermic oils, and molten salts are used as conventional working fluids [3]. Phase change materials were also proposed in order to increase the heat storage density [4]. However, these materials suffer from several limitations, such as high vapor pressure, high melting point, low thermal conductivity, in addition to an electrochemical behavior possibly leading to corrosion of metallic plant materials [5].
Ionic liquids (ILs) were suggested as efficient and sustainable working fluids in solar energy technologies thanks to their unique properties, such as low vapor pressure, high heat capacity, low melting point, and relatively high density [6,7]. Additionally, ILs possess high chemical stability, very low flammability and volatility, with subsequent low impact on the environment and health [8,9], and are relatively easy to tune for specific purposes just by changing the cation/anion pair or by modifying their functional groups [10].

Materials
The ionic liquid [BmPyrr]FAP (Scheme 1), MW = 587.27 g/mol, was purchased from Merck KGaA (purity: 99.0%; halides ≤ 100 ppm; water ≤ 100 ppm). The presence of wate in the commercial product was also checked using HRMAS NMR. The 1 H spectrum rec orded on the pure IL, without the addition of any solvent, did not show any water signal indicating that the water content is below the NMR detection limit (data not shown). The ionic liquid was heated in an oven at 200 °C for 168 h in the presence of a steel copper, or brass metal plate (2 cm × 2 cm × 0.07 cm) or with no metal plate. We used AIS 31XX series steel (wt%: Ni < 1.25, Cr < 0.60), commercial copper (purity > 99.9%), and rive brass (wt%: Cu 63, Zn 37). In order to check the nominal amounts, EDX analyses were performed on the metal plates prior to the immersion into the IL, confirming the expected values, except for steel, where only Fe was detected, because Ni and Cr contents are be low the detection limit. The metals/alloys used in this work were kindly provided by a company in Arezzo (Italy). At intermediate heating times (4 and 24 h), 1 mL of IL wa sampled for NMR spectroscopy and ICP-OES analyses. Table 1 summarizes the codes of the analyzed samples used throughout the text. The code of the initial non-heated sample is blank_0h.  19 F nuclei. A HRMAS 4 mm probe was used for 1 H, 13 C, and 31 P-based experi ments, whereas a 4 mm cross-polarization MAS probe was used for 19 F measurements DMSO-d6 (99.7% deuterated, Sigma) was added to the samples in order to, at least par tially, dissolve them and also for deuterium locking purposes. HRMAS 4 mm rotors with a 50 μL volume were used. For liquid samples, solutions with DMSO-d6 were prepared (1:1 volume ratio), and then 50 μL of each mixture was transferred to the rotor; in the case of solid or semi-solid samples, they were directly loaded into the rotor, in order to fill half of the rotor volume, and then added with about 20-30 μL DMSO-d6. Tetrame thylsilane was added for 1 H and 13 C internal spectral referencing. For 31 P and 19 F experi ments, the chemical shift (δ) scale was externally calibrated using CFCl3 (δ( 19 F): 0 ppm and 85% H3PO4 (δ( 31 P): 0 ppm). The ionic liquid was heated in an oven at 200 • C for 168 h in the presence of a steel, copper, or brass metal plate (2 cm × 2 cm × 0.07 cm) or with no metal plate. We used AISI 31XX series steel (wt%: Ni < 1.25, Cr < 0.60), commercial copper (purity > 99.9%), and rivet brass (wt%: Cu 63, Zn 37). In order to check the nominal amounts, EDX analyses were performed on the metal plates prior to the immersion into the IL, confirming the expected values, except for steel, where only Fe was detected, because Ni and Cr contents are below the detection limit. The metals/alloys used in this work were kindly provided by a company in Arezzo (Italy). At intermediate heating times (4 and 24 h), 1 mL of IL was sampled for NMR spectroscopy and ICP-OES analyses. Table 1 summarizes the codes of the analyzed samples used throughout the text. The code of the initial non-heated sample is blank_0h.  13 C, and 31 P-based experiments, whereas a 4 mm cross-polarization MAS probe was used for 19 F measurements. DMSO-d 6 (99.7% deuterated, Sigma) was added to the samples in order to, at least partially, dissolve them and also for deuterium locking purposes. HRMAS 4 mm rotors with a 50 µL volume were used. For liquid samples, solutions with DMSO-d 6 were prepared (1:1 volume ratio), and then 50 µL of each mixture was transferred to the rotor; in the case of solid or semi-solid samples, they were directly loaded into the rotor, in order to fill half of the rotor volume, and then added with about 20-30 µL DMSO-d 6 . Tetramethylsilane was added for 1 H and 13 C internal spectral referencing. For 31 P and 19 F experiments, the chemical shift (δ) scale was externally calibrated using CFCl 3 (δ( 19 F): 0 ppm) and 85% H 3 PO 4 (δ( 31 P): 0 ppm).
For selected samples, 1 H, 13 C, 31 P, and 19 F spectra were acquired. For 1 H, 13 C, 31 P, and 19 F nuclei excitation, 90 • pulses of 7, 12, 12, and 5 µs were used, respectively. 1 H spectra were acquired using the one pulse experiment, with a relaxation delay of 1-2 s and accumulating 64-1024 scans. 13 C spectra were recorded for samples blank_0h, brass_168h, and blank_168h only, using the Bruker zg30pg pulse sequence for NOE enhancement of carbon nuclei signals, using a relaxation delay of 2 s and accumulating 4k scans. 31 P spectra were recorded on samples blank_0h, blank_4h, blank_24h, blank_168h, steel_4h, steel_24h, steel_168h, brass_168h, and copper_168h only, using the one pulse experiment. A relaxation delay of 6 s was applied. 19 F spectra were recorded on samples blank_0h and blank_168h only, using the one pulse experiment with a relaxation delay of 3 s. The assignment of the signals in the 1 H spectrum of blank_0h was supported by 1 H-13 C heteronuclear single quantum coherence (HSQC) correlation experiment. One-dimensional (1D) selective 1 H total correlation spectroscopy (TOCSY) and HSQC experiments were also recorded on blank_168h for signal assignment of the cation degradation products. The HSQC experiment was also performed on brass_168h. The Bruker seldigpzs pulse sequence was used for the acquisition of 1 H 1D-TOCSY experiments, applying a Gaussian-shaped 180 • pulse for selective excitation. The relaxation delay was set to 1 s, and the mixing time to 80 ms. For the 1 H-13 C HSQC experiments, the Bruker hsqcetgpsisp2.2 pulse sequence was employed, with a relaxation delay of 1-1.5 s. All measurements were recorded using a MAS spinning rate of 6 kHz and maintaining the temperature at 298 K.

ICP-OES Measurements
The amount of the metals in the samples was quantified by ICP-OES. The mineralization was carried out with a Milestone Start D microwave digestor (FKV S.r.l., Torre Boldone, Italy). Weighed portions of approximately 100 mg of sample were treated with 6 mL HNO 3 (Fluka, TraceSELECT TM for trace analysis, >69%) and 2 mL H 2 O 2 (Supelco, Suprapur ® , 30%). After the thermal cycle in the closed vessels, the solutions were properly diluted with ultrapure water (18.2 MΩ·cm, PureLab Pro, ELGA LabWater, High Wycombe, Bucks, UK) for ICP-OES analysis. Calibration curves were obtained by dilution of commercial standard solutions (Fluka, TraceCERT©) in HNO 3 2%. ICP-OES measurements were carried out with an Optima 8000 ICP-OES (Perkin Elmer, Waltham, MA, USA) operating at 1500 W and equipped with an autosampler S10, MiraMist ® Nebulizer (Perkin Elmer, Waltham, MA, USA) and cyclonic chamber. Argon (420.069 nm) was used as the internal standard. Each element was measured at the following wavelengths

EDX Measurements
EDX acquisition was performed using an EDAX OCTANE detector mounted on a Tescan GAIA 3 FIB/SEM microscope. For the spectra acquisition, both 15 and 20 kV modes were used in order to assess changes in the elemental concentration within the bulk of steel_168h, copper_168h, and brass_168h. The values of the concentrations result from an average among 5 different spots. A tiny amount of each sample was placed on a stub with SEM conductive adhesive on top. EDX acquisition was performed on relatively thick (>200 µm) sample portions to minimize possible contributions to C, N, and O signals from the adhesive, which is constituted by these elements. For the quantification, we used the Kα lines of the metals. EDX acquisitions were performed under low magnification in order to minimize inhomogeneity effects on the quantification. Figure 1 shows the appearance of the original sample and of the samples heated for 4, 24, and 168 h in the presence of steel, copper, or brass plates, or in the absence of any plate. All the samples displayed a brown color after heating for 4 h, indicating that the thermal treatment degrades [BmPyrr]FAP ( Figure 1b). The color was more intense in the samples heated in the presence of the plates, particularly steel and copper, and became darker at longer heating times. After heating for 24 h (Figure 1c), a dark solid appears in the liquid heated in the presence of steel and copper. In these cases, only a spongy solid is left after 168 h, whereas in the sample containing brass and in the one with no metals, a highly viscous liquid can be observed (Figure 1d). samples heated in the presence of the plates, particularly steel and copper, and bec darker at longer heating times. After heating for 24 h (Figure 1c), a dark solid appea the liquid heated in the presence of steel and copper. In these cases, only a spongy sol left after 168 h, whereas in the sample containing brass and in the one with no meta highly viscous liquid can be observed (Figure 1d).

Characterization of the Thermal Degradation of the Cation
The thermal stability of the [BmPyrr] cation in the presence of steel, copper, or b was investigated by 1 H and 13 C NMR and compared to that in the absence of any al/alloy. The complete assignment of the cation 1 H and 13 C signals was obtained thank the acquisition of 1 H and 13 C one-dimensional spectra and of 1 H-1 H TOCSY and 1 H-HSQC two-dimensional experiments on the non-heated IL, i.e., blank_0h. The ass ment is reported in Table S1. 3.2.1. Thermal Degradation of the Cation in the Absence of the Metal/Alloy Figure 2 shows the 1 H HRMAS NMR spectra of the IL collected after diffe heating times in the absence of any metal/alloy. The main signals remain unaltered hough a slight broadening is observable upon increasing the heating time, probably to the increase in viscosity. This piece of evidence is in agreement with the work of gado et al., showing that the thermal degradation of [BmPyrr]FAP for more than 5 200 °C is hardly appreciable [27]. In the sample blank_168h, an intense peak resonatin about 8 ppm occurs, belonging to protons that do not show any direct correlation w 13 C nuclei, as highlighted in the 1 H-13 C HSQC spectrum ( Figure S1). This signal m

Characterization of the Thermal Degradation of the Cation
The thermal stability of the [BmPyrr] cation in the presence of steel, copper, or brass was investigated by 1 H and 13 C NMR and compared to that in the absence of any metal/alloy. The complete assignment of the cation 1 H and 13 C signals was obtained thanks to the acquisition of 1 H and 13 C one-dimensional spectra and of 1 H-1 H TOCSY and 1 H-13 C HSQC two-dimensional experiments on the non-heated IL, i.e., blank_0h. The assignment is reported in Table S1. Figure 2 shows the 1 H HRMAS NMR spectra of the IL collected after different heating times in the absence of any metal/alloy. The main signals remain unaltered, although a slight broadening is observable upon increasing the heating time, probably due to the increase in viscosity. This piece of evidence is in agreement with the work of Salgado et al., showing that the thermal degradation of [BmPyrr]FAP for more than 5 h at 200 • C is hardly appreciable [27]. In the sample blank_168h, an intense peak resonating at about 8 ppm occurs, belonging to protons that do not show any direct correlation with 13 C nuclei, as highlighted in the 1 H-13 C HSQC spectrum ( Figure S1). This signal might arise from water protons rapidly exchanging with labile protons of the degradation products of the anion presented in the following section. Low-intensity peaks, due to degradation products of the cation, progressively appear upon heating and can be detected if the vertical scale is magnified, as shown in the insets of Figure 3b for the sample heated for 168 h. Specifically, a peak appears at about 3.2 ppm due to a proton in Materials 2023, 16, 1762 6 of 17 an isolated spin system. This is evidenced by the selective 1 H TOCSY spectrum displayed in Figure S2b. This signal is also present in the 1 H-13 C HSQC spectrum ( Figure S1) and correlates with a 13 C signal at 51.5 ppm. Thus, we inferred that the 1 H and 13 C signals may arise from a methyl group linked to a heteronucleus (X-CH 3 , with X = O, N, P). By further expanding the intensity scale of the 1 H spectrum of blank_168h, it is possible to identify two doublets and one multiplet in the region between 5 ppm and 6 ppm; these three signals are present in the 1 H TOCSY spectrum recorded by irradiating the multiplet at 5.81 ppm ( Figure S2b), indicating that they arise from protons belonging to the same spin system. Based on the correlation signals detected in the 1 H-13 C HSQC spectrum of blank_168h (Table S2), we assigned them to 1 H and 13 C nuclei of a terminal vinyl group, probably belonging to a product of the Hoffman elimination of [BmPyrr], either involving the elimination of the butyl chain, leading to 1-butene, or the opening of the pyrrole ring [22,28]. The degradation product derived from the opening of the ring was already observed for [BmPyrr] and reported in Refs. [15,29].

Thermal Degradation of the Cation in the Absence of the Metal/Alloy
arise from water protons rapidly exchanging with labile protons of the degradation products of the anion presented in the following section. Low-intensity peaks, due to degradation products of the cation, progressively appear upon heating and can be detected if the vertical scale is magnified, as shown in the insets of Figure 3b for the sample heated for 168 h. Specifically, a peak appears at about 3.2 ppm due to a proton in an isolated spin system. This is evidenced by the selective 1 H TOCSY spectrum displayed in Figure S2b. This signal is also present in the 1 H-13 C HSQC spectrum ( Figure S1) and correlates with a 13 C signal at 51.5 ppm. Thus, we inferred that the 1 H and 13 C signals may arise from a methyl group linked to a heteronucleus (X-CH3, with X = O, N, P). By further expanding the intensity scale of the 1 H spectrum of blank_168h, it is possible to identify two doublets and one multiplet in the region between 5 ppm and 6 ppm; these three signals are present in the 1 H TOCSY spectrum recorded by irradiating the multiplet at 5.81 ppm ( Figure S2b), indicating that they arise from protons belonging to the same spin system. Based on the correlation signals detected in the 1 H-13 C HSQC spectrum of blank_168h (Table S2), we assigned them to 1 H and 13 C nuclei of a terminal vinyl group, probably belonging to a product of the Hoffman elimination of [BmPyrr], either involving the elimination of the butyl chain, leading to 1-butene, or the opening of the pyrrole ring [22,28]. The degradation product derived from the opening of the ring was already observed for [BmPyrr] and reported in Refs. [15,29].

Thermal Degradation of the Cation in the Presence of the Metal/Alloy
The presence of the brass metal plate during heating does not seem to promote further degradation of the IL cation; in fact, 1 H spectrum of brass_168h is quite similar to the one recorded for blank_168h ( Figure 3). In particular, in this case it is possible to detect a high intensity peak at about 6.3 ppm, which is not present in the 1 H-13 C HSQC spectrum, similarly to the one resonating at ~8 ppm in the 1 H spectrum of blank_168h. Also in this case, it is probably imputable to water protons exchanging with protons of the anion degradation products. Furthermore, in this spectrum, the low intensity peak at ~3.2 ppm, assigned to the X-CH3 product, and the barely detectable doublets resonating between 5.0 and 5.4 ppm, due to products of the Hoffmann elimination, are present also here and are characterized by intensities comparable to those observed for blank_168h. Therefore, the presence of brass does not seem to modify the thermal degradation pathways of the IL.
In the case of the IL heated in the presence of steel, the detailed analysis of the degradation products possibly formed after heating for more than 4 h was hampered by the significant line broadening detected on the 1 H NMR spectra of steel_24h and steel_168h ( Figure S3). This broadening could be ascribed to the presence of paramagnetic species derived from the partial dissolution of the metal plate, as detected by ICP-OES (see Section 3.4). However, the spectrum of steel_4h does not evidence the presence of degrada-

Thermal Degradation of the Cation in the Presence of the Metal/Alloy
The presence of the brass metal plate during heating does not seem to promote further degradation of the IL cation; in fact, 1 H spectrum of brass_168h is quite similar to the one recorded for blank_168h ( Figure 3). In particular, in this case it is possible to detect a high intensity peak at about 6.3 ppm, which is not present in the 1 H-13 C HSQC spectrum, similarly to the one resonating at~8 ppm in the 1 H spectrum of blank_168h. Also in this case, it is probably imputable to water protons exchanging with protons of the anion degradation products. Furthermore, in this spectrum, the low intensity peak at~3.2 ppm, assigned to the X-CH 3 product, and the barely detectable doublets resonating between 5.0 and 5.4 ppm, due to products of the Hoffmann elimination, are present also here and are characterized by intensities comparable to those observed for blank_168h. Therefore, the presence of brass does not seem to modify the thermal degradation pathways of the IL.
In the case of the IL heated in the presence of steel, the detailed analysis of the degradation products possibly formed after heating for more than 4 h was hampered by the significant line broadening detected on the 1 H NMR spectra of steel_24h and steel_168h ( Figure S3). This broadening could be ascribed to the presence of paramagnetic species derived from the partial dissolution of the metal plate, as detected by ICP-OES (see Section 3.4). However, the spectrum of steel_4h does not evidence the presence of degradation products, as observed for blank_4h ( Figure S3). This indicates a similar behavior up to 4 h of heating.
On the contrary, the 1 H spectra recorded for the IL heated with copper evidences the presence of degradation products already after 4 h of heating, even if the signals of the cation still dominate the spectrum for up to 24 h ( Figure S4b,c). Interestingly, almost complete degradation of the cation can be observed after 168 h. In fact, the signals of the cation are barely detectable, whereas broad signals show up in the region between 5 and 6 ppm. Moreover, a signal appears at~7.3 ppm, showing a triplet structure characterized by a J of about 50 Hz, which was ascribed to NH 4 + . This signal is diagnostic of the elimination of all substituents from the [BmPyrr] cation. It is worth noting that, as revealed by ICP-OES (see Section 3.4), the amount of copper detected in copper_168h is almost three times that detected in brass_168h, where the degradation is modest; this result suggests that the extensive degradation of the cation is promoted by a larger amount of copper.
To sum up, our measurements highlight a significant stability of the cation upon thermal treatment both in the absence and in the presence of all the metal plates up to 24 h; however, copper induces a considerable degradation after 168 h of thermal treatment.

Characterization of the Thermal Degradation of the Anion
31 P and 19 F NMR spectra were acquired for the characterization of the degradation of the FAP anion upon heating in the absence or in the presence of the metal/alloy plates. The 31 P and 19 F spectra of blank_0h are shown in Figure 4a and Figure S5a, respectively. They are consistent with those already reported in the literature for an IL containing FAP [30]; the 19 F spectrum highlights the presence of mer-FAP-type structure, consisting of spin sets displaying different chemical shifts, assigned to: (i) two chemically and magnetically equivalent fluorine atoms; (ii) the remaining fluorine atom; (iii) two chemically and magnetically equivalent pentafluoroethyl substituents; and (iv) the remaining pentafluoroethyl substituent. The complete 19 F assignment is reported in Table S3. The 31 P spectrum presents a main signal at −147.7 ppm with a complex multiplicity, due to 1-bond and 2-bond J P-F couplings between the phosphorous nucleus and the directly bound fluorine (P-F) and CF 2 , respectively. Furthermore, a second signal was detected in the region of phosphinic acids/phosphinates at −1.5 ppm, with a pentet multiplicity (J = 66 Hz) and an intensity of about 3% relative to the main peak ( Figure 4a); also in the 19 F spectrum, some low intensity peaks are detectable at −80.2 ppm (singlet) and at −125.0 ppm (doublet, J = 66 Hz) (Figure 5a). Based on their resonance frequencies and J coupling, these signals were assigned to CF 3 and CF 2 of bis(pentafluoroethyl)phosphinate (compound 1 of Scheme 2), respectively, in agreement with the literature [31]. This compound is known to be a hydrolysis product of the neutral precursor of FAP, tris(pentafluoroethyl)difluorophosphorane [32]. These data highlight that FAP undergoes a moderate degradation due to hydrolytic reactions even at room temperature. tion products, as observed for blank_4h ( Figure S3). This indicates a similar behavior up to 4 h of heating. On the contrary, the 1 H spectra recorded for the IL heated with copper evidences the presence of degradation products already after 4 h of heating, even if the signals of the cation still dominate the spectrum for up to 24 h ( Figure S4b,c). Interestingly, almost complete degradation of the cation can be observed after 168 h. In fact, the signals of the cation are barely detectable, whereas broad signals show up in the region between 5 and 6 ppm. Moreover, a signal appears at ~7.3 ppm, showing a triplet structure characterized by a J of about 50 Hz, which was ascribed to NH4 + . This signal is diagnostic of the elimination of all substituents from the [BmPyrr] cation. It is worth noting that, as revealed by ICP-OES (see Section 3.4), the amount of copper detected in copper_168h is almost three times that detected in brass_168h, where the degradation is modest; this result suggests that the extensive degradation of the cation is promoted by a larger amount of copper.
To sum up, our measurements highlight a significant stability of the cation upon thermal treatment both in the absence and in the presence of all the metal plates up to 24 h; however, copper induces a considerable degradation after 168 h of thermal treatment. 19 F NMR spectra were acquired for the characterization of the degradation of the FAP anion upon heating in the absence or in the presence of the metal/alloy plates. The 31 P and 19 F spectra of blank_0h are shown in Figures 4a and S5a, respectively. They are consistent with those already reported in the literature for an IL containing FAP [30]; the 19 F spectrum highlights the presence of mer-FAP-type structure, consisting of spin sets displaying different chemical shifts, assigned to: (i) two chemically and magnetically equivalent fluorine atoms; (ii) the remaining fluorine atom; (iii) two chemically and magnetically equivalent pentafluoroethyl substituents; and (iv) the remaining pentafluoroethyl substituent. The complete 19 F assignment is reported in Table S3. The 31 P spectrum presents a main signal at −147.7 ppm with a complex multiplicity, due to 1-bond and 2-bond JP-F couplings between the phosphorous nucleus and the directly bound fluorine (P-F) and CF2, respectively. Furthermore, a second signal was detected in the region of phosphinic acids/phosphinates at −1.5 ppm, with a pentet multiplicity (J = 66 Hz) and an intensity of about 3% relative to the main peak ( Figure 4a); also in the 19 F spectrum, some low intensity peaks are detectable at −80.2 ppm (singlet) and at −125.0 ppm (doublet, J = 66 Hz) (Figure 5a). Based on their resonance frequencies and J coupling, these signals were assigned to CF3 and CF2 of bis(pentafluoroethyl)phosphinate (compound 1 of Scheme 2), respectively, in agreement with the literature [31]. This compound is known to be a hydrolysis product of the neutral precursor of FAP, tris(pentafluoroethyl)difluorophosphorane [32]. These data highlight that FAP undergoes a moderate degradation due to hydrolytic reactions even at room temperature. The numbers 1-6 associated to the signals refer to the degradation products pictured in Scheme 2. In trace (d), the portion of the spectrum ranging from −162 to −133 ppm is magnified 20 times to evidence the signal of FAP. The signal due to compound 5, whose intensity is out of scale in trace (d), is shown in the inset scaled in intensity so that it is completely visible. The numbers 1-6 associated to the signals refer to the degradation products pictured in Scheme 2. In trace (d), the portion of the spectrum ranging from −162 to −133 ppm is magnified 20 times to evidence the signal of FAP. The signal due to compound 5, whose intensity is out of scale in trace (d), is shown in the inset scaled in intensity so that it is completely visible.

Thermal Degradation of the Anion in the Absence of the Metal/Alloy
Interestingly, the 31 P spectra of all samples collected during thermal treatment without the metal plates present new signals in the region of phosphates/phosphinates, between 5 and −25 ppm, which tend to evolve with heating time (Figure 4). Concomitantly, the main signal at −147.7 ppm progressively decreases in intensity and becomes barely detectable after 168 h of heating (Figure 4d). The decrease in intensity of the FAP signal as a function of time is reported in Figure 6, indicating a low stability of the anion to a prolonged thermal treatment, even in the absence of the metal/alloy plates. The almost complete degradation of the anion is also confirmed by the comparison of the 19 F spectra of original IL and of the IL heated for 168 h ( Figures S5 and 5), the latter presenting new peaks almost completely substituting the FAP signals. The asterisks (*) mark the spinning sidebands.

Thermal Degradation of the Anion in the Absence of the Metal/Alloy
Interestingly, the 31 P spectra of all samples collected during thermal treatment without the metal plates present new signals in the region of phosphates/phosphinates, between 5 and −25 ppm, which tend to evolve with heating time (Figure 4). Concomitantly, the main signal at −147.7 ppm progressively decreases in intensity and becomes barely detectable after 168 h of heating (Figure 4d). The decrease in intensity of the FAP signal as a function of time is reported in Figure 6, indicating a low stability of the anion to a prolonged thermal treatment, even in the absence of the metal/alloy plates. The almost complete degradation of the anion is also confirmed by the comparison of the 19 F spectra of original IL and of the IL heated for 168 h ( Figures S5 and 5), the latter presenting new peaks almost completely substituting the FAP signals. In order to identify the possible degradation products formed during heating, 31 P spectra ( Figure 4) were analyzed together with the 19 F spectrum of blank_168h (Figures 5b and S5b). Compared to the 31 P spectrum of the original IL, the spectrum of blank_4h (Figure 4b) presents one additional signal (doublet of triplets) at −8.2 ppm, which is assignable to a compound with a P atom linked to a fluorine atom and a pentafluoroethyl group; it was hypothesized that this signal belongs to pentafluoroethylfluorophosphinate, named compound 2 in Scheme 2. After 24 h of heating, the intensity of the signals of both compounds 1 and 2 in the 31 P spectrum increases ( Figure 4c); moreover, a new triplet with J = 952 Hz is detectable at −14.8 ppm, belonging to a species containing a phosphorous atom directly bound to two fluorine atoms; this signal is probably due to difluorophosphate (compound 3 of Scheme 2). In the spectrum of blank_168h (Figure 4d), the signal of compound 3 is no more detectable, whereas signals of compounds 1 and 2 persist, but have a lower intensity compared to that detected in the previous spectrum; moreover, several new signals can be observed, the more intense being a triplet at −4.9 ppm (J = 73 Hz); the same J coupling was found for the signal resonating at −125.3 ppm on the 19 F spectrum, and the two signals were assigned to pentafluoroethylphosphinate (compound 5 of Scheme 2), according with Mahmood et al. [31]. Furthermore, a doublet at −6.6 ppm (J = 902 Hz) was detected in the 31 P spectrum, which shares the same J coupling with the doublet resonating at −71.9 ppm in the 19 F spectrum, both signals being ascribable to monofluorophosphate (compound 4 of Scheme 2). A singlet at 0.1 ppm was observed in the 31 P spectrum and assigned to phosphate (compound 6 of Scheme 2). Finally, a singlet centered at~−148 ppm is present in the 19 F spectrum, probably due to F − . The complete set of 31 P and 19 F chemical shifts and J couplings of all the degradation compounds is reported in Tables 2 and 3. It should be noticed that our data do not allow us to determine the protonation state of the degradation compounds. All the compounds identified indicate that FAP underwent hydrolysis, but it is not possible to state whether hydrolysis occurred during heating or when the samples were unloaded from the oven. Anyway, 19 F and 31 P NMR data highlight that FAP undergoes severe degradation upon heating at 200 • C for 168 h even in the absence of any plate.
Materials 2023, 16, x FOR PEER REVIEW 11 of 18 Figure 6. Intensity of FAP signal as a function of heating time for the samples with no metal/alloy plates (red circles, samples blank_0h, blank_4h, blank_24h, and blank_168h) and with steel (blue triangles, samples steel_0h, steel_4h, steel_24h, and steel_168h) as obtained from the 31 P NMR spectra. The intensity is reported as the percentage of the total integral of each spectrum. The lines are added to guide the eye.
In order to identify the possible degradation products formed during heating, 31 P spectra ( Figure 4) were analyzed together with the 19 F spectrum of blank_168h (Figure 5b, Figure S5b). Compared to the 31 P spectrum of the original IL, the spectrum of blank_4h (Figure 4b) presents one additional signal (doublet of triplets) at −8.2 ppm, which is assignable to a compound with a P atom linked to a fluorine atom and a pentafluoroethyl group; it was hypothesized that this signal belongs to pentafluoroethylfluorophosphinate, named compound 2 in Scheme 2. After 24 h of heating, the intensity of the signals of both compounds 1 and 2 in the 31 P spectrum increases ( Figure 4c); moreover, a new triplet with J = 952 Hz is detectable at −14.8 ppm, belonging to a species containing a phosphorous atom directly bound to two fluorine atoms; this signal is probably due to difluorophosphate (compound 3 of Scheme 2). In the spectrum of blank_168h (Figure 4d), the signal of compound 3 is no more detectable, whereas signals of compounds 1 and 2 persist, but have a lower intensity compared to that detected in the previous spectrum; moreover, several new signals can be observed, the more intense being a triplet at −4.9 ppm (J = 73 Hz); the same J coupling was found for the signal resonating at −125.3 ppm on the 19 F spectrum, and the two signals were assigned to pentafluoroethylphosphinate (compound 5 of Scheme 2), according with Mahmood et al. [31]. Furthermore, a doublet at −6.6 ppm (J = 902 Hz) was detected in the 31 P spectrum, which shares the same J coupling with the doublet resonating at −71.9 ppm in the 19 F spectrum, both signals being ascribable to monofluorophosphate (compound 4 of Scheme 2). A singlet at 0.1 ppm was observed in the 31 P spectrum and assigned to phosphate (compound 6 of Scheme 2). Fi- Figure 6. Intensity of FAP signal as a function of heating time for the samples with no metal/alloy plates (red circles, samples blank_0h, blank_4h, blank_24h, and blank_168h) and with steel (blue triangles, samples steel_0h, steel_4h, steel_24h, and steel_168h) as obtained from the 31 P NMR spectra. The intensity is reported as the percentage of the total integral of each spectrum. The lines are added to guide the eye. Table 2. 31 P NMR chemical shifts and J P-F couplings assigned to the degradation compounds 1-6 pictured in Scheme 2. Signal multiplicity is reported in brackets. 3.3.2. Thermal Degradation of the Anion in the Presence of the Metal/Alloy 31 P spectra were also recorded for the IL heated for 168 h in the presence of the metal plates. These spectra are shown in Figure 7 in comparison with the one recorded for blank_168h. In the case of steel_168h, the main signal of FAP is no more detectable due to complete degradation; on the other hand, two broad signals appear at −0.3 and −4.5 ppm, probably mainly due to compound 5 and compound 6 of Scheme 2, already observed at similar frequencies in the spectrum of blank_168h. Here, the signals are quite broad because of the presence of paramagnetic iron species in the sample, as detected by ICP-OES and EDX. In the case of brass_168h, the remaining FAP ion accounts for only about 3% of the total 31 P spectrum integral, with degradation products appearing in the region between 1 and −17 ppm. Interestingly, signals ascribable to compounds 1 and 2 are quite narrow, while signals assigned to compounds 4, 5, and 6 are significantly broader; this result suggests that the last three species are in close proximity and might coordinate paramagnetic species dissolved in the sample, such as Cu(II). The 31 P spectrum of copper_168h shows extremely broad signals in the high frequency spectral region, abovẽ −50 ppm, probably due to the presence of a high amount of paramagnetic Cu(II), and the signal of FAP is no longer observable. This suggests a complete degradation of FAP also for this sample. Table 3. 19 F NMR chemical shifts and J P-F couplings assigned to specific fluorine nuclei of the degradation compounds 1-5 pictured in Scheme 2 and to the fluoride anion. Signal multiplicity is reported in brackets.

Species
19 F δ (ppm) a J P-F (Hz) Therefore, despite the fact that FAP has a higher stability to hydrolysis compared to the [PF 6 ] − anion, our data clearly show that it is not suitable for applications involving heating at high temperatures for prolonged times.

Detection of Elements in the Heated IL Using ICP-OES and EDX
The metals present in the plates were searched in the ionic liquid after thermal treatment by ICP-OES. In particular, in the case of the IL heated in the presence of the steel plate, Fe, Ni, and Cr were searched, and for the one heated with the copper plate, Cu was searched, whereas for the IL heated with the brass plate, Cu, Zn, and Sn were searched. In the ionic liquid heated in the absence of any metal plate, Fe, Ni, Cr, Cu, Sn, and Zn were searched and the metal contents were under detection limits for all heating times.
The metal contents of the samples heated in the presence of the metal plates at different heating times are reported in Table 4 and shown in Figure 8. Ni and Sn contents were under the detection limit in all samples. The data show that the metal content increases upon increasing the heating time. Fe and Zn contents in the ionic liquid heated for 168 h in the presence of steel and brass, respectively, are significantly higher than the copper amount detected in the case of the IL heated with the copper plate. Likewise, a smaller amount of copper than zinc was detected from the brass plate samples, demonstrating a lower tendency of Cu to be leached into the ionic liquid during heating with respect to Zn.

Detection of Elements in the Heated IL Using ICP-OES and EDX
The metals present in the plates were searched in the ionic liquid after thermal treatment by ICP-OES. In particular, in the case of the IL heated in the presence of the steel plate, Fe, Ni, and Cr were searched, and for the one heated with the copper plate, Cu was searched, whereas for the IL heated with the brass plate, Cu, Zn, and Sn were searched. In the ionic liquid heated in the absence of any metal plate, Fe, Ni, Cr, Cu, Sn, and Zn were searched and the metal contents were under detection limits for all heating times.
The metal contents of the samples heated in the presence of the metal plates at different heating times are reported in Table 4 and shown in Figure 8. Ni and Sn contents were under the detection limit in all samples. The data show that the metal content increases upon increasing the heating time. Fe and Zn contents in the ionic liquid heated for 168 h in the presence of steel and brass, respectively, are significantly higher than the copper amount detected in the case of the IL heated with the copper plate. Likewise, a smaller amount of copper than zinc was detected from the brass plate samples, demonstrating a lower tendency of Cu to be leached into the ionic liquid during heating with respect to Zn.  The EDX technique was used to detect elements associated with the IL (C, N, O, F, and P) and with the metal/alloy plate within the bulk of steel_168h, copper_168h, and brass_168h samples. Table 5 summarizes the average atomic percentages of each identified element for each sample. For steel_168h, EDX detected Fe as a "dissolved" element from the metal plate and Cu in copper_168h. The data collected from the ionic liquid containing the brass piece (brass_168h) showed only the presence of Zn dissolved and no Cu. The amounts of detected metals are consistent with those revealed by ICP-OES. In the case of brass_168h, Cu was not detected by EDX, probably due to a higher detection limit with respect to ICP-OES.  The EDX technique was used to detect elements associated with the IL (C, N, O, F, and P) and with the metal/alloy plate within the bulk of steel_168h, copper_168h, and brass_168h samples. Table 5 summarizes the average atomic percentages of each identified element for each sample. For steel_168h, EDX detected Fe as a "dissolved" element from the metal plate and Cu in copper_168h. The data collected from the ionic liquid containing the brass piece (brass_168h) showed only the presence of Zn dissolved and no Cu. The amounts of detected metals are consistent with those revealed by ICP-OES. In the case of brass_168h, Cu was not detected by EDX, probably due to a higher detection limit with respect to ICP-OES.  [BmPyrr]compound 6 (C 9 NO 4 P) without hydrogen atoms. b The number in brackets indicates the metal content expressed in mg g −1 .
By comparing the atomic percentages calculated for the pure IL (Table 5, column headed "[BmPyrr]FAP") and the ones of the analyzed samples (Table 5, columns headed "Steel_168h", "Copper_168h", and "Brass_168h"), a significant decrease in fluorine amount and a strong increase in oxygen can be noticed on the analyzed samples. Furthermore, an increase in phosphorous content is detectable. These trends can be rationalized considering the degradation products identified by NMR. Indeed, the atomic percentages calculated for the ionic pairs composed by [BmPyrr] and FAP main degradation prod-ucts (i.e. compounds 5 and 6, Since fluorine content decreases in the degraded samples, we can hypothesize the formation of volatile fluorine species, even if no evidence supporting this hypothesis was found in the literature, as the identification of FAP degradation products is still a rather unexplored subject.

Conclusions
In this work, we characterized the thermal degradation of [BmPyrr]FAP, which is a potential IL to be used for TES in solar energy applications. The IL was subjected to thermal treatment at 200 • C and monitored after 4, 24, and 168 h of heating. The effect of three different metal/alloys, i.e., steel, copper, and brass, on the thermal degradation of [BmPyrr]FAP was also studied. The conditions tested are relevant in solar-concentrating power plants. HRMAS NMR allowed us to characterize the degradation products of both the cation and the anion, while ICP-OES provided the content of metals dissolved in the ionic liquid and EDX was used for quantifying O and F content in the degraded IL. The NMR characterization showed that the cation is quite stable alone and against all the metals/alloys up to 24 h of heating. After 168 h, it is considerably degraded when heated in contact with copper, while it remains practically unchanged in the case of brass. Unfortunately, severe line broadening due to dissolved iron prevented us from ascertaining the cation stability against steel. On the other hand, the FAP anion completely degrades even in the absence of any metal/alloy, progressively undergoing hydrolysis reactions. FAP hydrolysis is quite noticeable considering the low amount of water dissolved in [BmPyrr]FAP in normal conditions. Steel and brass do not seem to sensibly affect the anion degradation. In fact, the main FAP degradation products are pentafluoroethylphosphinate and phosphate, as observed in the case of the IL degraded in the absence of metal/alloy. In all cases, these products are also present in similar relative amounts. Overall, our analysis highlights that [BmPyrr]FAP is not suitable to be employed for prolonged thermal exposure, even with no contact with metal/alloy plates, mainly due to the FAP anion. However, the [BmPyrr] cation shows a substantial thermal stability also when in contact with steel and brass, and can be considered a promising cation for the design of novel ILs to be used as working fluids for heat storage applications.
Supplementary Materials: The following supporting information can be downloaded at: https: //www.mdpi.com/article/10.3390/ma16051762/s1, Scheme S1: Numbering of the hydrogen atoms of [BmPyrr] used in the 1 H signal assignment reported in Table S1; Figure S1: 1 H-13 C HSQC spectrum of blank_168h; Figure S2: Comparison of 1 H spectrum of blank_168h (a) with 1D selective 1 H TOCSY obtained by irradiating the methyl protons of X-CH 3 at 3.17 ppm (b). Comparison of the 1 H spectral region ranging between about 4.5 and 6.0 ppm of blank_168h (c) with 1D selective 1 H TOCSY spectra obtained by irradiating H2 nucleus at 5.81 ppm (d) and H1b nucleus at 5.14 ppm (e) carried by the terminal vinyl group pictured in the inset; Figure S3: 1 H HRMAS NMR spectra of blank_0h (a), steel _4h (b), steel_24h (c) and steel_168h (d); Figure S4: 1 H HRMAS NMR spectra of blank_0h (a), copper _4h (b), copper_24h (c) and copper_168h (d). Residual water and DMSO are marked with asterisks; Figure S5: 19 F spectra of blank_0h (a) and blank_168h (b); Table S1: Assignment of 1 H and 13 C NMR signals of the [BmPyrr] cation according to the numbering reported in Scheme S1. Signal multiplicity and integration are reported in brackets; Table S2: Correlations between 1 H and 13 C nuclei of the degradation products, as detected from the 1 H-13 C HSQC spectrum. Signal multiplicity and integration are reported in brackets; Table S3: Assignment of 19 F NMR signals and 19 F-31 P J couplings (J P-F ) of the FAP anion of the investigated ionic liquid. The different colors are referred to fluorine atoms in different environments, as reported in the structure of Figure S5. Signal multiplicity and integration are reported in brackets.
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Informed Consent Statement: Not applicable.

Data Availability Statement:
The data presented in this study are available within the article or supplementary material and on request from the corresponding authors.