Bulletin of the Korean Chemical Society

  • 제35권7호
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  • Pages.2143-2147
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  • 2014
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  • 0253-2964(pISSN)
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  • 1229-5949(eISSN)
대한화학회 (Korean Chemical Society)
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Elimination Reactions of Aryl Furylacetates Promoted by R2NH-R2NH2 + in 70 mol% MeCN(aq). Effects of β-Aryl on the Ketene-Forming Transition-State

  • 투고 : 2014.03.26
  • 심사 : 2014.03.31
  • 발행 : 2014.07.20
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초록

Ketene-forming elimination from 2-X-4-nitrophenyl furylacetates (1a-d) promoted by $R_2NH-R_2NH_2{^+}$ in 70 mol % MeCN(aq) has been studied kinetically. When X = Cl and $NO_2$, the reactions exhibited second-order kinetics as well as Br$\ddot{o}$nsted ${\beta}$ = 0.37-0.54 and $|{\beta}_{lg}|$ = 0.31-0.45. The Br$\ddot{o}$nsted ${\beta}$ decreased with a poorer leaving group and $|{\beta}_{lg}|$ increased with a weaker base. The results are consistent with an E2 mechanism. When the leaving group was changed to a poorer one [X= H (1a) and $OCH_3$ (1b)], the reaction mechanism changed to the competing E2 and E1cb mechanisms. A further change to the E1cb mechanism was realized for the reaction of 1a with $i-Pr_2NH/i-Pr_2NH_2{^+}$ in 70 mol % MeCN-30 mol % $D_2O$. By comparing the kinetic results in this study with the existing data for $ArCH_2C(O)OC_6H_3-2-X-4-NO_2$, the effect of the ${\beta}$-aryl group on the ketene-forming elimination was assessed.

키워드

Introduction

Extensive studies of the structure-reactivity relationships in the ketene-forming elimination reactions have led to the qualitative understanding of the relationship between the reactant structure and the mechanism.1-11 Earlier, we reported that the ketene-forming elimination reactions from O-aryl phenylacetates (3) promoted by R2NH-R2NH2+ in 70 mol % MeCN(aq) proceeded by an E2 mechanism,11a while the reactions of O-aryl thienylacetates (2a-c) proceeded by a competing E2 and E1cb mechanism under the same condition.11g The results have been attributed to the higher acidity of the Cβ-H bond in the latter,12 which would stabilize the carbanion intermediate such that the E1cb mechanism can compete with the E2. Alternatively, the smaller aromatic resonance energy of the thiophene than that of benzene may also have contributed to the stability of the carbanion.13 To assess the relative importance of Cβ-H bond acidity and the aromatic resonance energy of the β-aryl group on the keteneforming eliminations, we have now studied the reactions of aryl furylacetates (1) with R2NH-R2NH2+ in 70 mol % MeCN(aq) (eq 1). Since the pKa values of 2-methylfuran and toluene are identical,12 whereas the aromatic resonance energy of furan is much lower than that of benzene,13 this seemed to be an ideal system for such a purpose. We have investigated the reaction mechanism under various conditions. By comparing with the existing data for eliminations of ArCH2C(O)OC6H3-2-X-4-NO2 [Ar = thiophene (2), phenyl (3)] with R2NH-R2NH2+ in 70 mol % MeCN(aq), the effect of β-aryl group was assessed.

 

Results

Aryl furylacetates 1a-d were synthesized by the reaction between 2-furylacetic acid, substituted phenols, 2-chloro-1-methylpyridinium iodide, and Et3N in CH2Cl2 as reported previously.11a,14 The spectral and analytical data for the new compounds were consistent with the proposed structures.

For the reactions of 1a-d with R2NH-R2NH2+ in 70 mol % MeCN(aq), the yields of aryloxides determined by comparing the UV absorption of the infinity samples of the kinetic runs with those of the authentic aryloxides were in the range of 94-98%. The rates of elimination reactions were followed by monitoring the increase in the absorption at the λmax for the aryloxides in the range of 400-434 nm. Excellent pseudofirst order kinetics plots, which covered at least three halflives were obtained. The rate constants are summarized in Tables S1-S4 in Supporting Information. For the reactions of 1c and 1d with R2NH-R2NH2+ in 70 mol % MeCN(aq), the plots of kobs versus base concentration were straight lines passing through the origin, indicating that the reactions are second-order, first order to the substrate and first order to the base (Figures 1, S8 and S9). The slopes are the overall second-order rate constants k2E. Values k2E for eliminations from 1c and 1d were summarized in Table 1.

Figure 1.Plots of kobs versus base concentration for eliminations from 2-chloro-4-nitrophenyl furylacetate (1c,■) and 2,4-dinitrophenyl furylacetate (1d,●) promoted by R2NH-R2NH2+ in 70 mol % MeCN(aq) at 25.0 ℃, [i-Pr2NH]/[i-Pr2NH2+] = 1.0, μ = 0.10 M (Bu4N+Br-).

Table 1.a[Substrate] = 5.0 × 10-5 M. b[R2NH] = 8.0 × 10-4- 5.0 × 10-2 M. cReference 15. dAverage of three or more rate constants. eEstimated uncertainty, ± 3%. fcis-2,6-Dimethylpiperidine.

In contrast to the reactions of 1c and 1d, the plots of kobs versus base concentration for the reactions of 1a and 1b were curves at low base concentration and straight lines at higher base concentration (Figures 2 and S1-S7). The data were analyzed with a nonlinear regression analysis program by assuming that the reaction proceeds by concurrent E2 and E1cb mechanisms (eq. 2).11a,11d By utilizing the computer program, the k2E, k1, and k-1/k2 values that best fit with Eq. (2) were calculated, and the plots were dissected into the E2 and E1cb components. In all cases, the correlations between the calculated and the experimental data were excellent. The calculated k2E values are included in Table 1 and k1 and k-1/k2 values are summarized in Table 2. The k1 increased and k-1/ k2 decreased with a stronger base. For a given base, k1 decreased and k-1/k2 ratio increased as the leaving group was changed to a poorer one.

Figure 2.Plots of kobs versus base concentration for eliminations from 4-nitrophenyl furylacetate (1a) promoted by R2NH-R2NH2+ in 70 mol % MeCN(aq) (●) and 70 mol % MeCN-30 mol % D2O (■) at 25.0 ℃, [i-Pr2NH]/[i-Pr2NH2+] = 1.0, μ = 0.10 M (Bu4N+Br-). The closed circles (●) and squares (■) are the experimental data, and the solid line shows the fitted curve by using eq. 2 (see text). The curve for the reaction in 70 mol % MeCN(aq) is dissected into the E2 and E1cb reaction components (dashed lines). Calculated values of k2E, k1, and k-1/k2 for 1a and 1b are summarized in Tables 1 and 2.

Table 2.a[Substrate] = 5.0 × 10-5 M. b[R2NH] = 8.0 × 10-4-5.0 × 10-2 M. cCalculated from kobs by using eq. 2. dThe slopes of the plots of log k1 versus pKa of the base for 1a and 1b are 0.38 ± 0.04 and 0.29 ± 0.12, respectively. eThe slopes of the plots of log k-1/k2 versus pKa of the base for 1a and 1b are -0.17 ± 0.12 and -0.27 ± 0.07, respectively. fSolvent was 70 mol % MeCN-30 mol % D2O. gcis-2,6-Dimethylpiperidine.

The k2E values for 1a-d showed excellent correlations with the pKa values of the promoting bases on the Brönsted plots (Figure 3). The β values are in the range of 0.37-0.54 and decrease with a better leaving group (Table 3).

Figure 3.Brönsted plots for the elimination from ArCH2C(O)-OC6H3-2-X-4-NO2 (Ar = furyl) promoted by R2NH-R2NH2+ in 70 mol % MeCN(aq) at 25.0 ℃ at 25.0 ℃ [X = H (1a,●), OMe (1b, ■), Cl (1c,▲), NO2 (1d,▼)].

Table 3.aReference 16.

When the reaction of 1a with i-Pr2NH/i-Pr2NH2+ was conducted in 70 mol % MeCN-30 mol % D2O, the kobs values were larger than those measured in 70 mol % MeCN(aq) (Figure 2 and Table S2), and the rate data could be fitted with the E1cb mechanism, that is, the 2nd term in Eq. (2). Calculated values of k1 and k-1/k2 for this reaction are summarized in Table 2.

The plots of the logk2E versus the leaving group pKlg values are depicted in Figure 4. As reported for 2a and 2b,11g the data for 1a and 1b showed large negative deviation from the straight lines. Therefore, the βlg values were calculated without the date for 1a and 1b. The βlg values are in the range 0.31-0.45 and decrease as the pKa value of the base increase (Table 4).

Figure 4.Plots log k2 versus pKlg values of the leaving group for the elimination from ArCH2C(O)OC6H3-2-X-4-NO2 (Ar = furyl, 1a-d) promoted by R2NH-R2NH2+ in 70 mol % MeCN(aq) at 25.0 ℃. [R2NH = Bn(i-Pr)NH (■), i-Bu2NH (▲), i-Pr2NH (●), 2,6-DMP (▼)].

Table 4.aReference 15. bcis-2,6-Dimethylpiperidine.

To provide additional evidence for the reaction mechanism, the H-D exchange experiment was conducted by mixing 1a with i-Pr2NH/i-Pr2NH2+in 70 mol % MeCN-30 mol % D2O at −10 ℃. The reactant was recovered immediately after mixing. The NMR spectrum indicated that approximately 35% of furfuryl C-H bond of 1a was converted to the C-D bond.

 

Discussion

Mechanism of Eliminations from 1. Results of kinetic investigations and product studies reveal that the reaction of 1c and 1d with R2NH-R2NH2+ in 70 mol % MeCN(aq) proceed by an E2 mechanism. The reactions produced elimination product and exhibited second-order kinetics, thereby ruling out all but bimolecular pathway. The (E1cb)R, (E1cb)ip, and internal return mechanisms, which would exhibit either a specific base catalysis or Brönsted β values near unity,16,17 were negated by the observed general base catalysis with the Brönsted β ranging from 0.37 to 0.54. Moreover, the β values increased with a poorer leaving group. This effect corresponds to a positive interaction coefficient, i.e., pxy = ∂β/∂pKlg, = ∂βlg/∂pKBH > 0, which describes the interaction between the base catalysis and the leaving group.17,18 The positive interaction coefficient provides additional support for an E2 mechanism in which the Cβ-H and Cα-OAr bonds are partially cleaved in the transition state.

When the leaving group was changed to a poorer one (1a and 1b), the plots of kobs versus the base concentration were curves (Figures 2 and S1-S7). The result could be explained with a competing E2 and E1cb mechanism, as explained below. First, the rate date fitted well with Eq. (2) and the shapes of dissected lines were typical for an E2 and E1cb mechanisms. Second, the calculated values of k2E, k1, and k-1/k2 are consistent with the competing mechanism; (i) The calculated k2E values for 1a and 1b and the experimentally measured k2E values for 1c and 1d show excellent correlation on the Brönsted plots (Figure 3), as expected for the E2 mechanism. (ii) The increase in the k1 value with a stronger base is in good agreement with the deprotonation step of the E1cb mechanism. (iii) The decrease in the k-1/k2 ratio with a stronger base can be attributed to the decreased acidity of the R2NH2+ which would reduce k-1.

It is interesting to note that the k2E values for 1a and 1b showed large negative deviation in Figure 4. This outcome could be explained, if the extent of the Cα-OAr bond cleavage is smaller than those for 1c and 1d. Since the β values for 1a and 1b are larger than those for 1c and 1d, the transition state of the E2 pathway would be skewed toward the E1cb-like with greater extend of proton transfer and smaller degree of cleavage of the Cα-OAr bond. This would destabilize the transition state as a result of the smaller extent of double bond formation due to the inefficient charge transfer from the β- to α-carbon and retard the rate. This result underlines the unusual sensitivity of the ketene-forming transition state to the reactant structure in the borderline between the E2 and E1cb.

The mechanistic diversity of the ketene-forming elimination was further demonstrated in the reaction of 1a with i-Pr2NH/i-Pr2NH2+ in 70 mol % MeCN-30 mol % D2O. There is convincing evidence in support of the mechanism change from the competing E2 and E1cb to E1cb under this condition. First, the kobs values measured in the deuterated solvent could be fitted to the 2nd term of Eq. (2), indicating an exclusive E1cb mechanism (Figure 2). Second, the larger k1 value in the deuterated solvent is also consistent because the basicity of R2NH would increase in the poorer solvating D2O.19 Third, since the k2 value should be almost the same in the two solvents, the 3-fold smaller k-1/k2 value in the deuterated solvent predicts that k-1H2O/k-1 D2O ≈ 3.0 (Table 2). Since all of the R2NH2+ should be converted to R2ND2+ in the deuterated solvent, the large primary isotope effect is not unexpected. Fourth, the smaller k-1D2O would increase the 2nd term of Eq. (2) more in the deuterated than in undeuterated solvent to make the kobs values larger. If it becomes the predominant term, a change of the mechanism would occur. Fifth, the partial H-D exchange of the furfuryl C-H bond in the recovered starting material from the reaction of 1a with i-Pr2NH/i-Pr2NH2+ in 70 mol % MeCN-30 mol % D2O provides additional support for the E1cb mechanism.

Effect of β-Aryl Group on the Ketene-Forming Transition State. Table 5 compares the rates and transition state parameters for the eliminations from ArCH2C(O)OC6H3-2-X-4-NO2. The relative rate of E2 reaction changed from 1.0 to 10 to 1.2 as the β-aryl group was varied from furyl (1a) to thienyl (2) to phenyl (3). Since the pKa values of 2-methyl furan, 2-methylthiophene, and toluene in DMSO are 43, 42, and 43, respectively,12 the faster rate observed for 2 can be attributed to the higher acidity of the Cβ-H bond. However, b and |βlg| values of 1a, 2, and 3 are almost the same within experimental errors, indicating that structure of the E2 transition states are not significantly influenced by the β-aryl group. In addition, the k1 value is larger for 2 than that for 1a is consistent with the higher acidity of the Cβ-H bond. The larger k-1/k2 value for 2 is as expected for the E1cb mechanism. Although the lower basicity of the conjugate base of 2 would reduce both k-1 and k2, the effect should be more pronounced for the slower step (k2). This would predict a larger k-1/k2. The most interesting result from this study is that 1a and 2, but not 3, showed mechanistic changes from E2 to a competing E2 and E1cb. While the change of the mechanism for 2 can be attributed to the higher acidity of the Cβ-H bond of 2 (see above), the difference between 1a and 3 cannot be explained similarly because the acidities of their Cβ-H bonds are the same. Alternatively, the negative charge density developed at the β-carbon can better be stabilized by the furyl than phenyl group because of the smaller aromatic resonance energy.13 This would stabilize the carbanion intermediate for 1a such that the E1cb mechanism can compete with E2. A similar explanation can be applied to the competing E2 and E1cb mechanisms for 2, although the higher acidity of the Cβ-H bonds would undoubtedly contribute to the carbanion stability.

Table 5.aReference 11g. bReference 11a. cR2NH = Bn(i-PrNH).

In conclusion, we have studied the elimination reactions of aryl furylacetates (1a-d) promoted by R2NH-R2NH2+ in 70 mol % MeCN(aq). The reactions of 1c and 1d proceeded by a concerted E2 mechanism. The mechanism changed to the competing E2 and E1cb mechanisms as the leaving group was changed to a poorer one [X = H (1a) and OCH3 (1b)]. For elimination from 1a with i-Pr2NH/i-Pr2NH2+, a further change to the E1cb mechanism was realized in 70 mol % MeCN-30 mol % D2O. When the β-aryl groups was changed from phenyl to thienyl to furyl, the structure of the E2 transition state remained almost the same although k2E value changed according to the acidity of the Cβ-H bond. Noteworthy is the mechanistic diversity observed in the keteneforming eliminations from 1 by the changes in the leaving group and the base-solvent system.

 

Experimental Section

Materials. Aryl furylacetates 1a-d were prepared from 2-furanacetic acid and substituted phenols in the presence of Et3N and 2-chloro-1-methylpyridinium iodide in CH2Cl2 as previously reported.11a,14 The yield (%), IR (KBr, C=O, cm-1), 1H NMR (400 MHz, CDCl3, J values are in Hz), and 13C NMR (100 MHz), and mass spectral data for the new compounds are as follows.

2-(4-Nitrophenyl)furylacetate (1a): Yield 75%; IR 1760 cm-1; 1H NMR δ 3.98 (s, 2H), 6.37 (m, 2H), 7.29 (d, J = 9.24, 2H), 7.41 (s, 1H), 8.25 (d, J = 9.24, 2H); 13C NMR δ 34.1, 108.8, 110.8, 122.4, 125.2, 142.6, 145.5, 146.2 ,155.2, 167.0; LRMS (EI); m/z 247 [M+] (64), 109 (12), 108 (79), 81 (100) ,82 (34), 63 (6), 53 (46), 50 (5).

2-(2-Methoxy-4-nitrophenyl)furylacetate (1b): Yield 78 %; IR 1774 cm-1; 1H NMR δ 3.90 (s, 3H), 3.99 (s, 2H), 6.38 (m, 2H), 7.20 (d, J = 8.56, 1H), 7.41 (d, J = 1.72, 1H), 7.83 (d, J = 2.4, 1H), 7.88 (dd, J = 2.4, 8.56, 1H); 13C NMR δ 33.7, 56.5, 107.7, 108.7, 110.7, 116.4, 123.1, 142.5, 144.9, 146.4, 146.5, 151.6, 166.5; LRMS (EI); m/z 277 [M+] (14), 108 (99), 81 (100), 53 (27).

2-(2-Chloro-4-nitrophenyl)furylacetate (1c): Yield 58 %; IR 1780 cm-1; 1H NMR δ 4.03 (s, 2H), 6.37 (m, 2H), 7.35 (d, J = 8.88, 1H), 7.42 (d, 1.72, 1H), 8.15 (dd, J = 2.72, 8.88, 1H), 8.33 (d, J = 2.72, 1H); 13C NMR δ 33.7, 109.0, 110.8, 123.2, 124.3, 125.9, 128.2, 142.7, 145.9, 151.9, 166.1; LRMS (EI); m/z 281 [M+] (42), 109 (14), 108 (29), 82 (64), 81 (100), 63 (11), 53 (53).

2-(2,4-Dinitrophenyl)furylacetate (1d): Yield 49%; IR 1745 cm-1; 1H NMR δ 4.08 (s, 2H), 6.39 (m, 1H), 7.42 (m, 1H), 7.50 (d, J = 9.06, 1H), 8.51 (dd, J = 2.72, 9.06, 1H), 8.96 (d, J = 2.72, 1H); 13C NMR δ 33.6, 109.3, 110.8, 121.3, 121.8, 126.7, 129.1, 131.6, 142.8, 145.4, 148.4, 166.3; LRMS (EI); m/z 292 [M+] (23), 125 (9), 108 (27), 82 (40), 81 (100), 53 (38).

Reagent grade acetonitrile and secondary amine were fractionally distilled from CaH2. The base-solvent solutions were prepared by dissolving equivalent amount of R2NH and R2NH2+ in 70 mol % MeCN(aq). In all cases, the ionic strength was maintained to 0.1 M with Bu4N+Br-.

Kinetic Studies. Reactions of 1a-d with R2NH/R2NH2+ in 70 mol % MeCN(aq) were followed by monitoring the increase in the absorbance of aryloxides at 400-434 nm with a UV-vis spectrophotometer as described.11a-11e

Product Studies. The products of eliminations from 1a-d promoted by R2NH/R2NH2+ in 70 mol % MeCN(aq) were identified as reported.11a The yields of aryloxides determined by comparing the UV absorptions of the infinity samples with those for the authentic aryloxides were in the range of 94-98%.

H-D Exchange Experiment. To determine whether the β-furfuryl protons of 1a undergo H-D exchange, 1a (0.047 g, 0.19 mmol) was reacted with i-Pr2NH/i-Pr2NH2+ (0.05 M, 5 mL) in 70 mol % MeCN-30 mol % D2O at −10 ℃. The reaction was quenched by adding dilute HCl(aq) immediately after mixing. The recovered reactant was isolated by extracting the products with ethyl acetate followed by the silca gel column chromatography using ethyl acetate/hexane = 1/4 as eluent. The proton NMR spectrum of the recovered reactant from 1a was identical to that of the substrate except that the integration at δ 3.98 decreased by approximately 35%.

Control Experiments. The stabilities of 1a-d were determined as reported.11b-11d The solutions of 1 in MeCN were stable for at least two weeks when stored in the refrigerator.

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피인용 문헌

  1. NH in MeCN: Effects of Base Solvent and β-Aryl Group on the Ketene-forming Transition State vol.38, pp.11, 2017, https://doi.org/10.1002/bkcs.11285