Introduction
A concerted mechanism involving a frontside nucleophilic attack was proposed for the anilinolysis of Y-aryl phenyl chlorothiophosphates [2; (YC6H4O)(PhO)P(=S)Cl] in acetonitrile (MeCN)1 based on the negative cross-interaction constant (CIC; ρXY = –0.22)2 and primary normal deuterium kinetic isotope effects (DKIEs; kH/kD = 1.11-1.33). The kinetic studies on the reactions of bis(Y-aryl) chlorothiophosphates [1; (YC6H4O)2P(=S)Cl] with substituted anilines and deuterated anilines are investigated kinetically in MeCN at 55.0 ± 0.1 ℃ (Scheme 1). The aim of this work is to study the dual substituent effects on the reaction mechanism where the substrate has the same substituent Y in each phenyl ring.
Scheme 1.Reactions of bis(Y-aryl) chlorothiophosphates (1) with XC6H4NH2(D2) in MeCN.
Results and Discussion
Table 1 lists the second-order rate constants of kH and kD with XC6H4NH2 and XC6H4ND2, respectively. The substituent effects on the rates are compatible with a typical nucleophilic substitution reaction. The stronger nucleophile leads to the faster rate with positive charge development at the nucleophilic nitrogen atom and a more electron-withdrawing substituent Y in the substrate leads to the faster rate with negative charge development at the reaction center phosphorus atom in the transition state (TS). However, the Hammett (log kH vs σY) plots for substituent Y variations in the substrates show biphasic concave upwards with a break point at Y = H (Fig. 1). The rate with aniline is always faster than its corresponding deuterated aniline, resulting in primary normal DKIEs (kH/kD > 1). The Hammett (ρX(H and D)) and Brönsted (βX(H and D)) coefficients for substituent X variations in the nucleophiles are summarized in Table 2, and the Hammett coefficients (ρY(H and D)) with Y are summarized in Table 3. The ρY(H and D) values are calculated from the plots of log k(H and D) against σY although all the studied substrates contain the two Y-substituted phenyl rings. The Hammett (log kH vs σX), Hammett (log kD vs σX), Brönsted [log kH vs pKa(X)] and Brönsted [log kD vs pKa(X)] plots with X, and Hammett (log kD vs σY) plots with Y are shown in Figures S1-S5, respectively (supporting information). The magnitudes of ρX, ρY and βX with anilines are larger than those with deuterated anilines. The magnitudes of ρX(H) (= –3.70 to –3.94) and βX(H) (= 1.30-1.39) values of 1 are comparable with those of 2 (ρX(H) = –3.81 to –4.01 and βX(H) = 1.34-1.41). The magnitudes of ρY(H and D) values with electron-withdrawing Y (= H, 3-MeO, 4-Cl) are much greater than those with electron-donating Y (= 4-MeO, 4-Me, H). From now on, for convenience, electron-donating Y (= 4-MeO, 4-Me, H) and electron-withdrawing Y (= H, 3-MeO, 4-Cl) substituents are described as e-d and e-w block, respectively.
Table 1.Second-Order Rate Constants (kH(D) × 105/M–1 s–1) of the Reactions of Bis(Y-aryl) Chlorothiophosphates (1) with XC6H4NH2(D2) in MeCN at 55.0 ℃
Table 2.aCorrelation coefficients (r) of ρX and βX values are better than 0.997
Table 3.aY = (4-MeO, 4-Me, H; e-d block). bY = (H, 3-MeO, 4-Cl; e-w block). a,bCorrelation coefficients (r) of ρY values are better than 0.982.
Figure 1.Hammett plots with Y of the reactions of bis(Y-aryl) chlorothiophosphates (1) with XC6H4NH2 in MeCN at 55.0 ℃.
When both the nucleophile and substrate have only one substituent X and Y, respectively, a Taylor series expansion of log kXY around σX = σY = 0 leads to Eq. (1).3 Herein, pure second- (e.g., ρXXσX 2 or ρYYσY 2), third- (e.g., ρXXYσX 2σY or ρXYYσXσY 2), and higher-derivative terms (e.g., ρXXXYσX 3σY or ρXXYYσX 2σY 2, etc) are neglected because they are normally too small to be taken into account. Figure 2 shows the positive values of ρXY(H) = 0.22 and 0.81 with e-d and e-w block, respectively. Figure S6 also shows the positive values of ρXY(D) = 0.28 and 0.59 with e-d and e-w block, respectively (supporting information). Both anilines and deuterated anilines, the magnitude of ρXY value with e-w block is larger than that with e-d block.4 This suggests that the distance between X and Y with e-w block is closer than that with e-d block in the TS (vide infra).5
In the present work, the modified Eq. (3) is introduced in which the cross-interaction between Y (in one phenyl ring) and Y (in the other phenyl ring) is included because all the studied substrates have identical substituent Y in each phenyl ring. The third and fourth terms on the right-side of Eq. (3) indicate the cross-interaction between X and two Y, and Y (in one phenyl ring) and Y (in the other phenyl ring), respectively. The value of ρYY(H) reflects the cross-interaction between the two substituents, Y and Y, in the TS. In Eq. (3), pure second-, third-, and higher-derivative terms are not considered as in Eq. (1). The values of ρX(H), ρY(H), ρXY(H) and ρYY(H) obtained by multiple regression are described in Eqs. (4) and (5) with e-d and e-w block, respectively. As a matter of course, the values of ρXY(H) = 0.22 [Eq. (4)] and 0.81 [Eq. (5)] with e-d and e-w block, respectively, have the same values calculated from Eq. (2) because ρXY is defined as ∂ρX/∂σY = ∂ρY/∂σX.
Figure 2.Plots of ρY(H) vs σX and ρX(H) vs σY of the reactions of bis(Y-aryl) chlorothiophosphates with XC6H4NH2 in MeCN at 55.0 ℃ to determine ρXY(H) according to Eq. (2). The values of ρXY(H) = 0.22 ± 0.10 (r = 0.992) and 0.81 ± 0.12 (r = 0.988) with (a) e-d and (b) e-w block, respectively, are obtained by multiple regression.
Note the sign and magnitudes of ρYY(H) values of –1.11 (negative and five times greater than ρXY(H)) and +11.1 (positive and fourteen times greater than ρXY(H)) with e-d and e-w block, respectively. The ρYY(D) values with deuterated anilines, –1.01 with e-d and 10.9 with e-w block, are quite similar to those with anilines.6 These results suggest that: (i) the values of ρYY(H) = –1.11 and 11.1 with e-d and e-w block, respectively, are attributed to the cross-interaction between Y and Y in each phenyl ring in the TS; (ii) the cross-interaction between the two substituents, Y and Y, is significant in the TS; (iii) the cross interaction between Y and Y with ew block is much greater than that with e-d block in the TS; (iv) the negative sign of ρYY(H) with e-d block indicates that the cross-interaction between Y and Y reduces the rate, i.e., negative role in the rate, whereas the positive sign of ρYY(H) with e-w block implies that the cross-interaction between Y and Y induces remarkable enhancement of the rate i.e., positive role in the rate; and finally (v) the opposite effect of the cross-interaction between Y and Y on the rate with e-d and e-w block leads to biphasic concave upward free energy relationship for substituent Y variations with a break point at Y = H.
The variation tendencies of the ρX and ρY values with Y and X, respectively, of 1 are opposite to those of 2. As a result, the sign of ρXY(H) with 1 is opposite to that of ρXY(H) with 2. This implies that an additional substituent Y to the other phenyl ring in the substrate changes the reaction mechanism from a concerted SN2 in 2 (based on ρXY(H) = –1.31) to a stepwise process with a rate-limiting leaving group departure from the intermediate in 1 (based on ρXY(H) = +0.22 and +0.81 with e-d and e-w block, respectively).5
The nonlinear free energy correlation of a concave upward plot is generally diagnostic of a change in the reaction mechanism, while nonlinear free energy correlation of the concave downward plot is generally interpreted as a rate-limiting step change from bond breaking with less basic nucleophiles to bond formation with more basic nucleophiles.7 In the present work, however, the concave upward free energy correlation with Y is interpreted as a change in the effect of the cross-interaction between Y and Y on the rate from negative with e-d block to positive role with e-w block.
The DKIEs can only be secondary inverse (kH/kD < 1.0) when an increase in the steric congestion occurs in the bondmaking process (e.g. TSb in Scheme 2) because the N–H(D) vibrational frequencies invariably increase upon going to the TS.8 In contrast, when partial deprotonation of the aniline occurs in a rate-limiting step by hydrogen bonding (e.g. TSf in Scheme 2), the kH/kD values are greater than unity, primary normal (kH/kD > 1.0).9 In the present work, the DKIEs are all primary normal (kH/kD 1.0; Table 4), indicating that partial deprotonation of the aniline occurs in a rate-limiting step by hydrogen bonding. The DKIEs invariably decrease as substituent X changes from electron-donating to electron-withdrawing, and invariably increase as substituent Y changes from electron-donating to electron-withdrawing. Accordingly, the max value of DKIE (kH/kD = 1.31) is observed with X = 4-MeO and Y = 4-Cl, indicating that the extent of the hydrogen bonding is the largest in the TS. The larger values of primary normal DKIEs with e-w block than those with e-d block indicate that the extent of hydrogen bond with e-w block is greater than that with e-d block in the TS. This is consistent with larger magnitude of the ρXY value with e-w block than that with e-d block (vide supra).
In summary, the authors propose a stepwise mechanism with a rate-limiting leaving group expulsion from the inter-mediate based on the positive ρXY values for both e-d and e-w blocks despite the biphasic concave upward free energy relationship, and dominant frontside nucleophilic attack involving a hydrogen bonded, four-center-type TSf based on the primary normal DKIEs. Concave upward free energy correlation with Y is ascribed to the opposite effect of the cross-interaction between Y and Y in the same substrate with e-d and e-w block.
Scheme 2.Backside attack in-line-type TSb and frontside attack hydrogen bonded, four-center-type TSf (L = H or D).
Table 4.aStandard error {= 1/kD[(ΔkH)2 + (kH/kD)2 × (ΔkD)2]1/2} from ref 10.
Table 5.Activation Parameters for the Reactions of Bis(Y-aryl) Chlorothiophosphates (1) with C6H5NH2 in MeCN
Activation parameters, enthalpies and entropies of activation, are determined as shown in Table 5. The enthalpies of activation are relatively low and entropies of activation are relatively large negative value. The relatively low values of activation enthalpies (7-9 kcal mol–1) and relatively large negative values of activation entropies (–49 to –57 cal mol–1 K–1) are typical for the aminolyses of P=S(O) systems.
Experimental Section
Materials. Bis(Y-aryl) chlorothiophosphates were prepared by reacting thiophosphoryl chloride with substituted phenol for 3 h in the presence of triethylamine in methylene chloride on cooling bath at –10.0 ℃ with constant stirring. Triethylamine hydrochloride was separated by filtration. The filtrate was treated with water-NaHCO3 and ether for work up after removal of solvent under reduced pressure. Ether extracted organic part was dried over anhydrous MgSO4 for 6-8 h. The product mixture was isolated by filtration and finally separated through column chromatography (silica gel, ethyl acetate/n-hexane) and dried under reduced pressure using oil diffusion pump and were identified by TLC, 1H-NMR, 13C-NMR, 31P-NMR and GC-MS. The physical constants after column chromatography (silicagel/ethylacetate + n-hexane) were as follows11 (supporting information);
Bis(4-methoxyphenyl) Chlorothiophophate: White solid crystal; mp 64.0-65.0 ℃; 1H-NMR (400 MHz, CDCl3 and TMS) δ 3.81 (s, 6H), 6.89-6.91 (d, 4H), 7.21-7.26 (d, 4H); 13C-NMR (100 MHz, CDCl3 and TMS) δ 55.6, 114.7, 122.2, 129.4, 140.1, 154.4; 31P-NMR (162 MHz, CDCl3 and TMS) d 66.6 (1P, P=S); GC-MS (EI, m/z) 344 (M+).
Bis(4-methylphenyl) Chlorothiophophate: White solid crystal; mp 54.0-55.0 ℃; 1H-NMR (400 MHz, CDCl3 and TMS) δ 2.36 (s, 6H), 7.19-7.21 (s, 8H); 13C-NMR (100 MHz, CDCl3 and TMS) δ 20.8, 121.0, 130.3, 136.1, 148.1; 31P-NMR (162 MHz, CDCl3 and TMS) δ 65.2 (1P, P=S); GC-MS (EI, m/z) 312 (M+).
Bis(3-methoxyphenyl) Chlorothiophophate: Liquid; 1HNMR (400 MHz, CDCl3 and TMS) δ 3.82 (s, 6H), 6.85-6.87 (t, 4H), 6.91-6.93 (d, 2H), 7.26-7.31 (m, 2H); 13C-NMR (100 MHz, CDCl3 and TMS) δ 55.53, 107.4, 112.2, 113.3, 130.1, 151.0, 160.7; 31P-NMR (162 MHz, CDCl3 and TMS) δ 63.6 (1P, P=S); GC-MS (EI, m/z) 344 (M+).
Bis(4-chlorophenyl) Chlorothiophophate: Liquid; 1HNMR (400 MHz, CDCl3 and TMS) δ 7.23 (d, 2H), 7.25 (d, 2H), 7.37 (d, 2H), 7.39 (d, 2H); 13C-NMR (100 MHz, CDCl3 and TMS) δ 122.6, 130.0, 132.2, 148.5; 31P-NMR (162 MHz, CDCl3 and TMS) δ 64.1 (1P, P=S); GC-MS (EI, m/z) 353 (M+).
Kinetics Measurement. The second-order rate constants and selectivity parameters were obtained as previously described.1 Initial concentrations were as follows; [substrate] = 5 × 10−3 M and [nucleophile] = (0.10-0.30) M.
Product Analysis. Diphenyl chlorothiophosphate was reacted with excess aniline for more than 15 half-lives at 55.0 ℃ in MeCN. Solvent was evaporated under reduced pressure. The product mixture was treated with ether by a work-up process with dilute HCl and dried over anhydrous MgSO4. Then the product was isolated through column chromatography (30% ethyl acetate/n-hexane) and then dried under reduced pressure. The analytical and spectroscopic data of the product gave the following results (supporting information):
[(C6H5O)2P(=S)NHC6H5]: Brown liquid; 1H-NMR (400MHz, CDCl3 and TMS) δ 3.39 (s, br., 1H), 6.68-6.70 (m, 5H), 6.74-6.78 (m, 3H), 7.13-7.22 (m, 6H), 7.27-7.38 (m, 1H); 13C-NMR (100 MHz, CDCl3 and TMS) δ 118.3, 118.4, 121.3, 121.4, 122.9, 125.6, 129.6, 138.9, 150.3; 31P-NMR (162 MHz, CDCl3 and TMS) δ 62.6 (1P, P=S); GC-MS (EI, m/z) 341 (M+).
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