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Article

Kinetic Study of the Diels–Alder Reaction between Maleimide and Furan-Containing Polystyrene Using Infrared Spectroscopy

1
Department of Polymer Science and Engineering, School of Chemical Engineering, Dalian University of Technology, Dalian 116024, China
2
SINOPEC (Beijing) Research Institute of Chemical Industry Co., Ltd., Beijing 100013, China
*
Authors to whom correspondence should be addressed.
Polymers 2024, 16(3), 441; https://doi.org/10.3390/polym16030441
Submission received: 8 December 2023 / Revised: 29 January 2024 / Accepted: 31 January 2024 / Published: 5 February 2024
(This article belongs to the Section Polymer Analysis and Characterization)

Abstract

:
The Diels–Alder (D–A) reaction between furan and maleimide is a thermally reversible reaction that has become a vital chemical technique for designing polymer structures and functions. The kinetics of this reaction, particularly in polymer bulk states, have significant practical implications. In this study, we investigated the feasibility of utilizing infrared spectroscopy to measure the D–A reaction kinetics in bulk-state polymer. Specifically, we synthesized furan-functionalized polystyrene and added a maleimide small-molecule compound to form a D–A adduct. The intensity of the characteristic absorption peak of the D–A adduct was quantitatively measured by infrared spectroscopy, and the dependence of conversion of the D–A reaction on time was obtained at different temperatures. Subsequently, the D–A reaction apparent kinetic coefficient kapp and the Arrhenius activation energy Ea,D–A were calculated. These results were compared with those determined from 1H-NMR in the polymer solution states.

1. Introduction

The Diels–Alder (D–A) reaction, also known as the [4 + 2] cycloaddition reaction, was first proposed by Otto Diels and Kurt Alder. This reaction, which belongs to the click chemical reaction system [1], is not only a general method for the synthesizing of six-membered rings [2,3], but also one of the most extensively studied thermal reversible equilibrium reactions. The D–A reaction is a one-step synergetic reaction with a reversible process, and due to the absence of ionic reaction, it exhibits high adaptability to the reaction environment. The reaction produces a D–A cycloaddition product at low temperature, while a retro-Diels–Alder (rD–A) reaction occurs at high temperature, leading to the conversion of D–A cycloaddition back into the initial reactants [4]. Furan/maleimide (and its derivatives) is the most widely studied thermoreversible D–A reaction system [5,6]. The efficient construction of macromolecules based on the D–A reaction between furan and maleimide has become an interesting research field [7,8,9,10,11,12]. For instance, researchers can conveniently construct polymers with self-healing functions [13,14,15,16,17,18] or recycle thermosetting materials [19] by employing the D–A reaction. Furthermore, bifuran and bismaleimide can be utilized as monomers to fabricate polymers with complex structures directly through stepwise polymerization reaction [20,21]. However, due to the complexity of the reactions between macromolecules, it is crucial to study the kinetics of the D–A reaction in polymer systems.
Currently, the kinetics of the D–A reaction are studied using a range of methods including UV spectroscopy [17,22,23], 1H-NMR spectroscopy [24], rheological testing [25,26], and a combination of various techniques [27,28]. Gandini et al. [22] used UV spectroscopy to investigate the reaction kinetics of furfuryl acetate and N-methylmaleimide. The conversion of the D–A reaction at a certain time was determined by monitoring the variation in the conjugate characteristic peak of C=C-C=O in maleimide at 300 nm, and the Arrhenius activation energy Ea was reported as 40 ± 3 kJ mol−1. Wang et al. [24] utilized in situ 1H-NMR spectroscopy to study the D–A and rD–A reaction kinetics in linear polyurethanes synthesized by the D–A reaction. By analyzing the variation in the D–A characteristic peak intensity with temperature, the authors confirmed that the D–A reaction followed second-order kinetic law and determined the Ea to be 47 kJ mol−1. Polgar et al. [25] investigated the D–A reversible reaction in ethylene–propylene rubber using rheological testing. The researchers deduced that the D–A reaction followed second-order kinetics, while the rD–A reaction followed first-order kinetics by measuring the change in polymer modulus with time. The Ea,D–A was found to be 7.04 kJ mol−1 at 60~80 °C, and the Ea,rD–A was 57.9 kJ mol−1 at 130~140 °C. Additionally, the change in enthalpy and the change in entropy of the reaction were determined. In previous work, we synthesized thermoreversibly crosslinked ethylene–propylene rubber based on the D–A reaction and investigated its kinetics using rheological testing [29,30,31]. It was revealed that the structure of maleimide, as well as the molar ratio of maleimide to furan, influenced the Ea and the apparent kinetic coefficient k. By adjusting the furan/maleimide ratio, the Ea value was decreased from 51.78 kJ mol−1 to 19.29 kJ mol−1. These studies have significantly contributed to our understanding of the D–A reaction in polymer systems.
However, there exist practical obstacles when utilizing the aforementioned techniques to examine kinetics in polymer systems. For instance, UV and 1H-NMR spectroscopies are not ideal for detecting polymers that lack appropriate solvents across a broad temperature range, such as polyethylene and isotactic polypropylene. Furthermore, rheological methods are not suitable for analyzing D–A reactions in highly crystalline polymers or those with high glass transition temperatures, as rheological tests necessitate the polymers to remain in viscoelastic states. In addition, since polymers are predominantly used in bulk (i.e., without solvent), the studies of the D–A reaction in polymer bulk states are more important. Infrared spectroscopy is a classical analytical tool that is highly suited to bulk polymer analysis. Many studies qualitatively demonstrated the reversibility of the D–A reaction using this technique [32,33,34,35]. For instance, Singha et al. [36] employed FTIR to investigate the D–A reaction in the homopolymers of furfuryl methacrylate, finding that the rD–A reaction followed the first-order kinetic law with the Ea,rD–A of 54.25 kJ mol−1. Bose et al. [37] employed a combination of FTIR and rheological analyses to study the kinetics of the rD–A reaction in a one-system D–A polymer, which combined furan and maleimide groups with a polymethacrylate copolymer. They determined the Ea of the rD–A reaction to be 64.8 kJ mol−1.
The kinetics of the rD–A reaction reflect the material’s reprocessability, while the kinetics of the D–A reaction reflect the recoverability of the material properties. Notably, the D–A reaction in polymers is affected not only by temperature, but also by the structure and mobility of the reactant groups. In this paper, we demonstrate that infrared spectroscopy can be used for the quantitative calculation of the D–A reaction conversion and Ea, and the accuracy of the results is verified using 1H-NMR spectroscopy.

2. Experiment

2.1. Materials

Styrene (St, 99%), N-phenylmaleimide (99%), 1-dodecyl-1H-pyrrole-2,5-dione (95%), and 2,2′-Azobisisobutyronitrile (AIBN) were purchased from Energy Chemical, Beijing, China. The styrene was washed with 10% aqueous NaOH, dried over magnesium sulfate, and then fractionally distilled under reduced pressure.

2.2. Synthesis of Furan-Functionalized Polystyrene (PSF)

Furan-functionalized styrene (fSt) was synthesized by reference to the literature method [38]. The poly (St-co-fSt), PSF, was prepared via free radical polymerization. The synthesis route of PSF is shown in Scheme 1. In a typical process, 61.7 mmol fSt, 144.0 mmol styrene (St), and 0.56 g initiator AIBN were added to a flask under the protection of a nitrogen atmosphere, and the product was collected after polymerization at 60 °C for 5 h. The produced polymer was dissolved in dichloromethane and precipitated in methanol. The resulting precipitate was washed using dichloromethane to remove the unreacted monomers and initiators. The product was filtered and vacuum-dried at 40 °C before being characterized by 1H-NMR spectroscopy (Figure S1).

2.3. Diels–Alder Reaction of PSF with Maleimides

The cycloaddition product of PSF with N-phenylmaleimide (Ma), PSF-Ma, formed by the D–A reaction was synthesized as follows: PSF and Ma (with the molar ratio of furan/maleimide = 1/2) were dissolved in dichloromethane, and then the solution was heated under reflux in a nitrogen atmosphere for 24 h at 40 °C. The resulting product was precipitated in methanol, and the unreacted monomers were washed using dichloromethane and dried under vacuum at 40 °C. The structural analysis showed that 25.0% of the furyl group in the PSF underwent the D–A reaction.
The cycloaddition product of PSF with 1-dodecyl-1H-pyrrole-2,5-dione (Mb), PSF-Mb, was prepared as follows: PSF and Mb (with the molar ratio of furan/maleimide = 1/2) were dissolved in chloroform, and the solution was heated under reflux in a nitrogen atmosphere for 24 h at 60 °C. The product was precipitated in methanol and the unreacted monomers were washed away with hexane, and finally dried under vacuum at 40 °C. The structural analysis showed that 19.7% of the furyl group in the PSF underwent the D–A reaction.

2.4. Characterization

Nuclear magnetic resonance spectra (1H-NMR) were recorded on a Vaian DLG 400 MHz spectrometer (Vaian, CA, USA) using C2D2Cl4. Fourier-transform infrared spectroscopy (FTIR) spectra were obtained using a Nicolet 6700 FTIR spectrometer (ThermoFisher, Waltham, MA, USA), and the transmission mode with 32 scans was applied.

3. Results and Discussion

Two furan/maleimide systems were designed to investigate the kinetics of the thermoreversible D–A reaction. The furan moiety was incorporated into polystyrene (PSF) through the copolymerization of styrene (70 mol%) and furyl-functionalized styrene (30 mol%). The maleimide moiety was a small molecule with either aromatic or aliphatic substituent groups, denoted as Ma and Mb, respectively, as illustrated in Figure 1.

3.1. Diels–Alder Reaction between PSF and Ma

The reversible D–A reaction between PSF and Ma is presented in Scheme 2. The formation of the D–A cycloaddition product PSF-Ma was identified by FTIR. Figure 2 compares the FTIR spectra of PSF, Ma, and PSF-Ma. The characteristic absorption peaks at 1777, 1712, 1379, and 1188 cm−1 [32,37], which emerge or increase in intensity, are representative of the PSF-Ma adduct.
By gradually increasing the temperature of the infrared spectroscopy pool from 30 °C to 150 °C, and observing the FTIR spectra of PSF-Ma, as depicted in Figure 3A, it was discovered that the intensity of the C-N vibration peak at 1188 cm−1 steadily decreased, while cooling the sample pool from 150 °C to 30 °C resulted in an increase in the intensity of this peak, as shown in Figure 3B. This indicates that the D–A/rD–A reaction in the bulk state of the PSF/Ma system can be monitored by measuring the absorption at 1188 cm−1. The D–A cycloaddition product PSF-Ma was heated to 150 °C, and an infrared spectrum was obtained every 2 min to observe the changes in the sample structure over time, as shown in Figure 3C. It was observed that the peak at 1188 cm−1 gradually weakened with time at 150 °C, indicating the gradual dissociation of D–A cycloaddition in PSF-Ma via the rD–A reaction occurring at high temperature. Furthermore, when the dissociated PSF/Ma was rapidly cooled from 150 °C to 70 °C to induce the D–A cycloaddition reaction, as illustrated in Figure 3D, the gradual increase in absorption at 1188 cm−1, with a detection interval of 2 min, demonstrated the feasibility of determining the D–A conversion variation at a specific time in the PSF-Ma bulk state using FTIR.
The kinetics of the D–A reaction were investigated by monitoring the FTIR absorbance at 1188 cm−1 at different temperatures. Initially, it is assumed that the D–A equilibrium is dominated by the D–A cycloaddition reaction at low temperatures and by the dissociation reaction of the D–A adduct at high temperatures, as shown in Scheme 2. For kinetic studies, a simplified n-level reaction model is often used to derive the corresponding kinetics equations (Equation (1)) [25], where kapp is the apparent kinetic coefficient, and x is the reaction conversion at time t. When the reaction kinetic order n is 1, 2, and 3, Equation (1) can be converted to Equations (2)–(4), respectively.
d x d t = k a p p ( 1 x ) n
ln 1 1 x = k 1 t ( n = 1 )
1 1 x = k 2 t ( n = 2 )
( 1 1 x ) 2 = k 3 t ( n = 3 )
In this work, the D–A reaction conversion x was determined by absorbance at 1188 cm−1 from Equation (5):
x = A t A 0 A 30   ° C A 150   ° C , 30 min
where At and A0 are the absorbance value at the designed temperature at time t = t and t = 0, respectively; and A30 °C and A150 °C, 30min are the absorbance at 30 °C (the end of the D–A reaction) and the absorbance at 150 °C after 30 min (the end of the rD–A reaction). The following steps were adopted: (1) keeping the D–A cycloaddition product PSF-Ma at 150 °C for 30 min to ensure that the rD–A reaction had totally completed; (2) rapidly cooling the infrared spectroscopy sample pool to the designed temperature; and (3) reading the absorbance at 1188 cm−1 at different times to calculate the D–A reaction conversion x according to Equation (5). The D–A reaction between the PSF and Ma was performed at six different temperatures, namely, 40 °C, 50 °C, 60 °C, 70 °C, 80 °C, and 90 °C. The absorbance was recorded with time and is presented in Figure S2. Using Equation (5), the relationship between x and time at different temperatures in the D–A reaction is plotted in Figure 4. It is evident that x increased almost linearly with time, and the slope of the curves increased with the temperature until it reached its maximum at 70 °C. Further increasing the temperature to 80 °C and 90 °C resulted in a decline in the slope, indicating that the rD–A reaction could not be ignored at these temperatures.
At a certain temperature, the apparent kinetic coefficient kapp of the D–A reaction was determined from the conversion data by fitting the x to Equations (2), (3), and (4), respectively, and the resulting slope was k1, k2, k3, as shown in Figure 5. The kapp values are summarized in Table 1, and the linear fits were found to be satisfactory, with R2 values close to 1. To determine the Arrhenius activation energy, Ea,D–A, of the D–A reaction, the kapp values at different temperatures were used to construct Arrhenius plots, as shown in Figure 6. The slope of the plot corresponds to Ea,D–A, while the intercept corresponds to the pre-exponential factor k0,D–A, as defined by Equation (6).
ln k a p p = E a , D A R T + ln k 0 , D A
All of the first-, second-, and third-order coefficients (k1, k2, k3) increased with increasing temperature from 40 °C to 70 °C, but decreased at 80 °C. This trend suggested that heating promoted the rapid completion of the D–A reaction within the temperature range of 40~70 °C, whereas at 80 °C, the reaction was influenced by the rD–A process. The Ea,D–A was calculated based on the data obtained at 40 °C, 50 °C, 60 °C, and 70 °C, and the resulting value of Ea,D–A was approximately 50 kJ mol−1, as shown in Table 1. It was observed that both second-order and third-order kinetics fit the entire temperature range. To further determine the kinetics reaction order, additional studies utilizing 1H-NMR spectroscopy will be conducted.
PSF-Ma was characterized using 1H-NMR spectroscopy. Figure 7 presents the assignments for the various resonances, including those that distinguish between endo and exo D–A stereoisomers. Compared to PSF, PSF-Ma exhibited characteristic D–A peaks at 5.37 ppm, 3.96~4.23 ppm, 3.65~3.78 ppm, and 3.01~3.11 ppm. The composition of PSF-Ma can be determined by analyzing the characteristic peak integral at 3.96~4.23 ppm, combined with the integral at 3.96~4.44 ppm. The results indicate that 25.0 mol% of the furyl group in PSF underwent the D–A reaction, and the F/M ratio (molar ratio of furan and maleimide) in the PSF-Ma was 4:1.
In order to investigate the kinetics of the D–A reaction, the in situ 1H-NMR spectroscopy was utilized, which further validated the precision of the FTIR results. A temperature cycle was performed, ranging from 25 °C to 120 °C, to obtain a variable temperature 1H-NMR spectrum, as depicted in Figure 8. The reaction between PSF and Ma in the PSF-Ma was carried out in C2D2Cl4 (under a nitrogen atmosphere) and characterized using real-time 1H-NMR spectroscopy. The analysis of the 1H-NMR spectra of the PSF-Ma revealed a continuous decrease in the D–A characteristic peaks at 5.37 ppm, 3.96~4.23 ppm, 3.65~3.78 ppm, and 3.01~3.11 ppm, while the characteristic peak of D–A at 4.44 ppm increased during the heating process, indicating the occurrence of the rD–A reaction at high temperatures. Conversely, during the cooling process, the characteristic peaks exhibited an opposite trend, indicating the occurrence of the D–A reaction at low temperatures.
The PSF-Ma adduct was subjected to the rD–A reaction at 120 °C, followed by cooling to various temperatures (40 °C, 50 °C, 60 °C, 70 °C, and 80 °C) for 2 h in C2D2Cl4, as shown in Figure S3. The reaction was carried out in a 1H-NMR tube under a nitrogen atmosphere and monitored in real time using 1H-NMR spectroscopy. One spectrum was scanned every 10 min. The results showed that the characteristic peak of D–A adduct completely disappeared after 20 min at 120 °C, indicating the occurrence of the rD–A reaction at high temperature. As the temperature was gradually lowered to below 80 °C, the characteristic peak of D–A adducts steadily increased with the extension of time, indicating the occurrence of the D–A reaction at low temperature. The feasibility of calculating the variation in the conversion x with time using in situ 1H-NMR was confirmed. The D–A reaction conversion x was determined from Equation (7):
x = 2 A c A 3 + A m + A c = 2 ( A g + A h ) A 3 + A m + A c
where A3, Ac, Am, Ag, and Ah denote the integrated areas of the peaks 3, c, m, g, and h, respectively. The relationship between x and time at each temperature is illustrated in Figure 9. Within the temperature range of 40~70 °C, an increase in temperature corresponds to an accelerated conversion at a constant reaction time. However, a decline in x is evident at temperatures exceeding 80 °C, signifying the commencement of the rD–A reaction. Accordingly, it is inferred that the optimal temperature for the D–A reaction is 70 °C, where the conversion attains its maximum.
The kinetics of the D–A reaction during the initial 120 min were simulated using 1H-NMR analysis, as illustrated in Figure 10. The first-, second-, and third-order coefficients (k1, k2, k3) were calculated and are listed in Table 1. It was observed that the values of k1, k2, and k3 increased as the temperature increased from 40 °C to 70 °C, but decreased at 80 °C. This suggests that a moderate increase in temperature within the range of 40~70 °C is beneficial for promoting the rapid completion of the D–A reaction. Comparing the results of three series, it was found that the linear fitting value R2 for the second-order kinetics fit the data accurately, which implied that the D–A reaction between PSF and Ma followed second-order kinetics. The Ea,D–A and the k0,D–A were determined using data obtained at temperatures of 40 °C, 50 °C, 60 °C, and 70 °C, as shown in Figure S4. The calculated Ea,D–A was found to be 55.35 kJ mol−1 (second-order kinetics), which closely aligns with the results obtained by FTIR.

3.2. Diels–Alder Reaction between PSF and Mb

Scheme 3 illustrates the reversible D–A reaction between PSF and Mb. The resulting D–A cycloaddition product, PSF-Mb, was identified by FTIR. Figure 11 presents a comparison of the FTIR spectra of PSF, Mb, and PSF-Mb. The emergence or intensification of the characteristic absorption peaks at 1772, 1702, 1397, and 1281 cm−1 provide clear evidence of the PSF-Mb adduct.
Figure 12A shows a gradual decrease in the intensity of the C-N vibration at 1397 cm−1 as the temperature of the PSF-Mb sample was increased from 30 °C to 150 °C, whereas a corresponding increase in the intensity of this peak was observed upon cooling the sample from 150 °C to 30 °C, as shown in Figure 12B. These observations suggest that monitoring the absorption at 1397 cm−1 enables the tracking of the D–A/rD–A reaction in PSF-Mb. Similar to the PSF/Ma system, the PSF/Mb D–A cycloaddition product was subjected to heating at 150 °C, and infrared spectra were collected every 2 min to observe changes in the sample structure over time; subsequently, the PSF-Mb sample was cooled to 70 °C, and spectra were collected every 2 min, as shown in Figure S5.
The D–A reaction between PSF and Mb was conducted at temperatures of 40 °C, 50 °C, 60 °C, 70 °C, 80 °C, and 90 °C. The absorbance was recorded over time, and the resulting data are shown in Figure S6. By employing Equation (5), the relationship between x and time was calculated at various temperatures during the D–A reaction and is plotted in Figure 13. The data reveal that the slope of the curves decreased as the temperature exceeded 80 °C, similar to the trend observed in the PSF/Ma system.
The apparent kinetic coefficient kapp of the D–A reaction in PSF-Mb was determined from Figure S7 based on Equations (2)–(4), and the resulting k1, k2, and k3 values are presented in Table 2. Based on the R2 values, both first-order kinetics and second-order kinetics were found to fit the entire temperature range. Figure S8 depicts the relationship between k and temperature. The Ea,D–A was calculated using Equation (6) based on the data obtained at 40 °C, 50 °C, 60 °C, and 70 °C, and the resulting values of Ea,D–A were found to be approximately 60~80 kJ mol−1, as shown in Table 2. Notably, the second-order kinetics results fit the data well.
PSF-Mb was characterized using 1H-NMR spectroscopy, as presented in Figure 14. In comparison with PSF, PSF-Mb displayed distinct D–A peaks at chemical shifts of 5.15~5.35 ppm, 3.75~4.28 ppm, 3.55~3.65 ppm, 3.20~3.36 ppm, and 2.70~3.05 ppm. The composition of PSF-Mb can be determined by the characteristic peak integral at 3.75~4.28 ppm in conjunction with the integral at 3.75~4.75 ppm. The results indicate that 19.7 mol% of the furyl group in PSF underwent the D–A reaction, and the F/M ratio (molar ratio of furan and maleimide) in PSF-Mb was found to be 5:1.
The reaction between PSF and Mb was conducted in C2D2Cl4 under nitrogen, and the reaction progress was monitored in real time using 1H-NMR spectroscopy. A temperature cycle ranging from 25 °C to 120 °C was employed to obtain a variable-temperature 1H-NMR spectrum, as depicted in Figure 15. To investigate the kinetics of the D–A reaction, the PSF-Mb adduct was subjected to the rD–A reaction at 120 °C and subsequently cooled to various temperatures (40 °C, 50 °C, 60 °C, 70 °C, and 80 °C) for 2 h in C2D2Cl4, as shown in Figure S9. The real-time 1H-NMR spectrum was acquired every 10 min at each designed temperature, following the measurement method utilized in the PSF/Ma system. The results showed that the characteristic peak of the D–A adduct disappeared completely after 20 min at 120 °C, indicating the occurrence of the rD–A reaction at high temperature. The D–A reaction conversion x was calculated based on Equation (7), and the relationship between x and time at each temperature is depicted in Figure 16.
The kinetics of the D–A reaction were monitored using 1H-NMR, as shown in Figure S10. The k1, k2, and k3 values were calculated and are listed in Table 2. The values of k1, k2, and k3 increased as the temperature rose from 40 °C to 70 °C, but decreased at 80 °C, indicating that 40~70 °C is optimal for promoting the rapid completion of the D–A reaction. Additionally, the second-order kinetics fit the data accurately, as evidenced by the linear fitting value R2, indicating that the D–A reaction between PSF and Mb may follow second-order kinetics. By analyzing the data obtained at temperatures of 40 °C, 50 °C, 60 °C, and 70 °C, the Ea,D–A and k0,D–A for the reaction were determined, as shown in Figure S11. The calculated Ea,D–A (second-order) was 41.53 kJ mol−1.
By comparing the experimental results obtained by 1H-NMR and FTIR at 70 °C, it was observed that the value of k2 for the PSF/Mb system in the bulk state (determined by FTIR) was 3.09 × 10−2 min−1·mol−1·L, whereas that in the solution state (determined by 1H-NMR) was 1.04 × 10−3 min−1·mol−1·L. This represents a difference of an order of magnitude between the two systems. Moreover, the Ea,D–A values of the two systems were significantly different: 69.59 kJ mol−1 for the bulk system and 41.53 kJ mol−1 for the solution system. This is in contrast to the experimental results obtained for the PSF/Ma system. We propose that the reason for this difference is that both PSF and Ma molecules contain phenyl, which results in their structural similarity, enabling good miscibility and mutual melting between the two reactants, thus facilitating mutual diffusion and reaction in solution or in bulk state. This similarity leads to the similar calculated k and Ea,D–A in the two states. However, in the PSF/MB system, the Mb molecule contains a long alkyl substituent, which is less compatible with the PSF polymer than the Ma molecule. This may result in the local aggregation of Mb after the rD–A reaction between PSF and Mb in the bulk state, resulting in a higher local concentration and a faster rate of the D–A reaction in the bulk state than in solution.

4. Conclusions

In this work, polystyrene containing furan substituents PSF was synthesized via the copolymerization of styrene and furan-functionalized styrene, and the PSF was further reacted with two different structurally designed maleimide small molecules, Ma and Mb, in a D–A reaction to produce PSF-Ma and PSF-Mb adducts, respectively. The reversible D–A reaction kinetics of the PSF/Ma and PSF/Mb systems in the bulk state were investigated using infrared spectroscopy, and the reaction kinetic parameters, including the apparent kinetic coefficient kapp, the Arrhenius activation energy Ea,D–A, and pre-exponential factor k0,D–A, were calculated. The D–A reaction kinetics of these two systems were also studied using 1H-NMR in solution, and the results were compared with those from infrared spectroscopy. The results showed that the infrared spectroscopy provided reliable data for studying the D–A reaction kinetics in the PSF/Ma system, as the Ea,D–A and kapp values obtained from the infrared spectra in the bulk state were comparable to those obtained from the 1H-NMR spectra in solution. However, in the PSF/Mb system, the Ea,D–A value obtained from the infrared spectra was significantly higher than that obtained from the 1H-NMR spectra, while the kapp value showed a similar trend. The poor compatibility between aliphatic Mb and aromatic PSF in the bulk polymer matrix caused the heterogeneous environment, which is considered to be the main reason for the inconsistency between the results obtained from the bulk- and solution-state experiments. These results inspired us to consider the compatibility between substituents on furan and maleimide moieties when designing D–A reactants, as it might directly affect the efficiency of the D–A reaction and even the final properties of the materials.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/polym16030441/s1, Figure S1: 1H-NMR spectra of monomers St and fSt, homopolymers PS and PF, and copolymer PSF. Figure S2: The FTIR absorbance during the D–A reaction between PSF and Ma recorded with time at different temperatures: 40 °C, 50 °C, 60 °C, 70 °C, 80 °C and 90 °C. Figure S3: The 1H-NMR spectra during the D–A reaction between PSF and Ma recorded with time at different temperatures: 40 °C, 50 °C, 60 °C, 70 °C and 80 °C. Figure S4: Fitting the Arrhenius plot to (A) first-order, (B) second-order, and (C) third-order reaction to determine the Ea,D–A and k0,D–A of the D–A reaction between PSF and Ma based on the 1H-NMR results. Figure S5: FTIR spectra of (A) holding the temperature at 70 °C for 60 min and (B) holding the temperature at 150 °C for 20min. Figure S6: The FTIR absorbance during the D–A reaction between PSF and Mb recorded with time at different temperatures: 40 °C, 50 °C, 60 °C, 70 °C, 80 °C and 90 °C. Figure S7: The FTIR absorbance during the D–A reaction between PSF and Mb recorded with time at different temperatures: 40 °C, 50 °C, 60 °C, 70 °C, 80 °C and 90 °C. Figure S8: Fitting the Arrhenius plot to (A) first-order, (B) second-order, and (C) third-order reaction to determine the Ea,D–A and k0,D–A of the D–A reaction between PSF and Mb based on the FTIR results. Figure S9: The 1H-NMR spectra during the D–A reaction between PSF and Mb recorded with time at different temperatures: 40 °C, 50 °C, 60 °C, 70 °C and 80 °C. Figure S10: Fitting the conversion data to (A) first-order, (B) second-order, and (C) third-order reaction kinetics to determine the apparent kinetic coefficient kapp of D–A reaction between PSF and Mb at 40 °C, 50 °C, 60 °C, 70 °C and 80 °C based on the 1H-NMR results. Figure S11: Fitting the Arrhenius plot to (A) first-order, (B) second-order, and (C) third-order reaction to determine the Ea,D–A and k0,D–A of the D–A reaction between PSF and Mb based on the 1H-NMR results.

Author Contributions

Methodology, D.G.; Software, H.Y.; Investigation, T.W.; Resources and software, X.W.; Data curation, J.Z.; Supervision, H.N. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China (No. 22278065).

Institutional Review Board Statement

Not applicable.

Data Availability Statement

Data are contained within the article and Supplementary Materials.

Conflicts of Interest

The authors Dali Gao, Hua Yin, Jiawei Zhao, and Xingguo Wang were employed by the company SINOPEC. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

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Scheme 1. Synthesis route of furan-functionalized polystyrene PFS.
Scheme 1. Synthesis route of furan-functionalized polystyrene PFS.
Polymers 16 00441 sch001
Figure 1. Furan/maleimide systems designed in this work.
Figure 1. Furan/maleimide systems designed in this work.
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Scheme 2. Reversible Diels–Alder reaction between PSF and Ma.
Scheme 2. Reversible Diels–Alder reaction between PSF and Ma.
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Figure 2. FTIR spectra of PSF, Ma, and PSF-Ma.
Figure 2. FTIR spectra of PSF, Ma, and PSF-Ma.
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Figure 3. FTIR spectra of (A) the heating procedure of PSF-Ma from 30 °C to 150 °C, (B) the cooling procedure of PSF-Ma from 150 °C to 30 °C, (C) holding the temperature at 150 °C for 30 min, and (D) holding the temperature at 70 °C for 60 min.
Figure 3. FTIR spectra of (A) the heating procedure of PSF-Ma from 30 °C to 150 °C, (B) the cooling procedure of PSF-Ma from 150 °C to 30 °C, (C) holding the temperature at 150 °C for 30 min, and (D) holding the temperature at 70 °C for 60 min.
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Figure 4. Dependence of conversion x on reaction time in PSF/Ma system derived from FTIR results at 40 °C, 50 °C, 60 °C, 70 °C, 80 °C, and 90 °C, respectively.
Figure 4. Dependence of conversion x on reaction time in PSF/Ma system derived from FTIR results at 40 °C, 50 °C, 60 °C, 70 °C, 80 °C, and 90 °C, respectively.
Polymers 16 00441 g004
Figure 5. Fitting the conversion data to (A) first-order, (B) second-order, and (C) third-order reaction kinetics to determine the apparent kinetic coefficient kapp of D–A reaction between PSF and Ma at 40 °C, 50 °C, 60 °C, 70 °C, and 80 °C based on the FTIR results.
Figure 5. Fitting the conversion data to (A) first-order, (B) second-order, and (C) third-order reaction kinetics to determine the apparent kinetic coefficient kapp of D–A reaction between PSF and Ma at 40 °C, 50 °C, 60 °C, 70 °C, and 80 °C based on the FTIR results.
Polymers 16 00441 g005
Figure 6. Fitting the Arrhenius plot to (A) first-order, (B) second-order, and (C) third-order reaction to determine the Ea,D–A and k0,D–A of the D–A reaction between PSF and Ma based on the FTIR results.
Figure 6. Fitting the Arrhenius plot to (A) first-order, (B) second-order, and (C) third-order reaction to determine the Ea,D–A and k0,D–A of the D–A reaction between PSF and Ma based on the FTIR results.
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Figure 7. 1H-NMR spectra of PSF, Ma, and PSF-Ma. (* solvent: C2D2Cl4).
Figure 7. 1H-NMR spectra of PSF, Ma, and PSF-Ma. (* solvent: C2D2Cl4).
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Figure 8. 1H-NMR spectra of PSF-Ma at variable temperatures. (* solvent: C2D2Cl4).
Figure 8. 1H-NMR spectra of PSF-Ma at variable temperatures. (* solvent: C2D2Cl4).
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Figure 9. Dependence of conversion x on reaction time in PSF/Ma system derived from 1H-NMR results at 40 °C, 50 °C, 60 °C, 70 °C, and 80 °C, respectively.
Figure 9. Dependence of conversion x on reaction time in PSF/Ma system derived from 1H-NMR results at 40 °C, 50 °C, 60 °C, 70 °C, and 80 °C, respectively.
Polymers 16 00441 g009
Figure 10. Fitting the conversion data to (A) first-order, (B) second-order, and (C) third-order reaction kinetics to determine the apparent kinetic coefficient kapp of D–A reaction between PSF and Ma at 40 °C, 50 °C, 60 °C, 70 °C, and 80 °C based on the 1H-NMR results.
Figure 10. Fitting the conversion data to (A) first-order, (B) second-order, and (C) third-order reaction kinetics to determine the apparent kinetic coefficient kapp of D–A reaction between PSF and Ma at 40 °C, 50 °C, 60 °C, 70 °C, and 80 °C based on the 1H-NMR results.
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Scheme 3. Reversible Diels–Alder reaction between PSF and Mb.
Scheme 3. Reversible Diels–Alder reaction between PSF and Mb.
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Figure 11. FTIR spectra of PSF, Mb, and PSF-Mb.
Figure 11. FTIR spectra of PSF, Mb, and PSF-Mb.
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Figure 12. FTIR spectra of (A) the heating procedure of PSF-Mb from 30 °C to 150 °C and (B) the cooling procedure of PSF-Mb from 150 °C to 30 °C.
Figure 12. FTIR spectra of (A) the heating procedure of PSF-Mb from 30 °C to 150 °C and (B) the cooling procedure of PSF-Mb from 150 °C to 30 °C.
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Figure 13. Dependence of conversion x on reaction time in PSF/Mb system derived from FTIR results at 40 °C, 50 °C, 60 °C, 70 °C, 80 °C, and 90 °C, respectively.
Figure 13. Dependence of conversion x on reaction time in PSF/Mb system derived from FTIR results at 40 °C, 50 °C, 60 °C, 70 °C, 80 °C, and 90 °C, respectively.
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Figure 14. 1H-NMR spectra of PSF, Mb, and PSF-Mb. (* solvent: C2D2Cl4).
Figure 14. 1H-NMR spectra of PSF, Mb, and PSF-Mb. (* solvent: C2D2Cl4).
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Figure 15. 1H-NMR spectra of PSF-Mb at variable temperatures. (* solvent: C2D2Cl4).
Figure 15. 1H-NMR spectra of PSF-Mb at variable temperatures. (* solvent: C2D2Cl4).
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Figure 16. Dependence of conversion x on reaction time in PSF/Mb system derived from 1H-NMR results at 40 °C, 50 °C, 60 °C, 70 °C, and 80 °C, respectively.
Figure 16. Dependence of conversion x on reaction time in PSF/Mb system derived from 1H-NMR results at 40 °C, 50 °C, 60 °C, 70 °C, and 80 °C, respectively.
Polymers 16 00441 g016
Table 1. Kinetics parameters of the Diels–Alder reaction between PSF and Ma.
Table 1. Kinetics parameters of the Diels–Alder reaction between PSF and Ma.
Kinetic OrderMethodkapp (k1/min−1, k2/min−1·mol−1·L, k3/min−1·mol−2·L2)k0, D–A
/min−1·mol1−n·Ln−1
Ea, D–A
/kJ mol−1
40 °C50 °C60 °C70 °C80 °C
n = 1FTIR5.44 × 10−4
(R2 = 0.918)
8.02 × 10−4
(R2 = 0.983)
1.13 × 10−3
(R2 = 0.981)
3.08 × 10−3
(R2 = 0.971)
2.50 × 10−3
(R2 = 0.990)
7.62 × 10449.17
(R2 = 0.915)
1H-NMR5.21 × 10−4
(R2 = 0.995)
7.70 × 10−4
(R2 = 0.994)
1.41 × 10−3
(R2 = 0.995)
2.86 × 10−3
(R2 = 0.996)
2.20 × 10−3
(R2 = 0.994)
1.43 × 10550.84
(R2 = 0.977)
n = 2FTIR5.50 × 10−4
(R2 = 0.918)
8.20 × 10−4
(R2 = 0.984)
1.18 × 10−3
(R2 = 0.982)
3.38 × 10−3
(R2 = 0.976)
2.73 × 10−3
(R2 = 0.992)
1.89 × 10551.54
(R2 = 0.914)
1H-NMR5.38 × 10−4
(R2 = 0.995)
8.05 × 10−4
(R2 = 0.994)
1.54 × 10−3
(R2 = 0.995)
3.45 × 10−3
(R2 = 0.998)
2.53 × 10−3
(R2 = 0.995)
8.16 × 10555.35
(R2 = 0.971)
n = 3FTIR1.11 × 10−3
(R2 = 0.919)
1.68 × 10−3
(R2 = 0.985)
2.45 × 10−3
(R2 = 0.983)
7.43 × 10−3
(R2 = 0.981)
5.97 × 10−3
(R2 = 0.992)
9.46 × 10553.92
(R2 = 0.911)
1H-NMR1.11 × 10−3
(R2 = 0.994)
1.69 × 10−3
(R2 = 0.994)
3.35 × 10−3
(R2 = 0.993)
8.37 × 10−3
(R2 = 0.995)
5.82 × 10−3
(R2 = 0.992)
9.67 × 10659.96
(R2 = 0.964)
Table 2. Kinetics parameters of the Diels–Alder reaction between PSF and Mb.
Table 2. Kinetics parameters of the Diels–Alder reaction between PSF and Mb.
Kinetic OrderMethodkapp (k1/min−1, k2/min−1·mol−1·L, k3/min−1·mol−2·L2)k0, D–A
/min−1·mol1−n·Ln−1
Ea, D–A
/kJ mol−1
40 °C50 °C60 °C70 °C80 °C
n = 1FTIR3.01 × 10−3
(R2 = 0.989)
4.01 × 10−3
(R2 = 0.994)
1.00 × 10−2
(R2 = 0.993)
2.16 × 10−2
(R2 = 0.991)
9.64 × 10−3
(R2 = 0.989)
3.35 × 10760.68
(R2 = 0.954)
1H-NMR2.65 × 10−4
0.987
4.60 × 10−4
0.995
8.00 × 10−4
0.993
9.78 × 10−4
0.990
8.66 × 10−4
0.996
1.37 × 10340.11
(R2 = 0.973)
n = 2FTIR3.32 × 10−3
(R2 = 0.987)
4.59 × 10−3
(R2 = 0.993)
1.42 × 10−2
(R2 = 0.996)
3.09 × 10−2
(R2 = 0.979)
1.31 × 10−2
(R2 = 0.971)
1.11 × 10969.59
(R2 = 0.955)
1H-NMR2.69 × 10−4
(R2 = 0.988)
4.73 × 10−4
(R2 = 0.996)
8.39 × 10−4
(R2 = 0.993)
1.04 × 10−3
(R2 = 0.991)
9.13 × 10−4
(R2 = 0.997)
2.40 × 10341.53
(R2 = 0.975)
n = 3FTIR7.35 × 10−3
(R2 = 0.983)
1.05 × 10−2
(R2 = 0.989)
4.08 × 10−2
(R2 = 0.984)
9.07 × 10−2
(R2 = 0.949)
3.61 × 10−2
(R2 = 0.939)
9.62 × 101079.18
(R2 = 0.952)
1H-NMR5.47×10−4
(R2 = 0.988)
9.73×10−4
(R2 = 0.996)
1.76×10−3
(R2 = 0.991)
2.23×10−3
(R2 = 0.991)
1.93×10−3
(R2 = 0.996)
8.95×10343.12
(R2 = 0.978)
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Wang, T.; Gao, D.; Yin, H.; Zhao, J.; Wang, X.; Niu, H. Kinetic Study of the Diels–Alder Reaction between Maleimide and Furan-Containing Polystyrene Using Infrared Spectroscopy. Polymers 2024, 16, 441. https://doi.org/10.3390/polym16030441

AMA Style

Wang T, Gao D, Yin H, Zhao J, Wang X, Niu H. Kinetic Study of the Diels–Alder Reaction between Maleimide and Furan-Containing Polystyrene Using Infrared Spectroscopy. Polymers. 2024; 16(3):441. https://doi.org/10.3390/polym16030441

Chicago/Turabian Style

Wang, Tongtong, Dali Gao, Hua Yin, Jiawei Zhao, Xingguo Wang, and Hui Niu. 2024. "Kinetic Study of the Diels–Alder Reaction between Maleimide and Furan-Containing Polystyrene Using Infrared Spectroscopy" Polymers 16, no. 3: 441. https://doi.org/10.3390/polym16030441

APA Style

Wang, T., Gao, D., Yin, H., Zhao, J., Wang, X., & Niu, H. (2024). Kinetic Study of the Diels–Alder Reaction between Maleimide and Furan-Containing Polystyrene Using Infrared Spectroscopy. Polymers, 16(3), 441. https://doi.org/10.3390/polym16030441

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