Kinetic Study of the Alkaline Hydrolysis of 1,n‐Bis(4‐cyanopyridinium)alkanes: Charge Density and New Conformational Effects on the Reactivity of 1,3‐Bis(4‐cyanopyridinium)propane

The alkaline hydrolysis reaction rates of 1,n‐bis(4‐cyanopyridinium)alkane derivatives C_nbis(CP)²⁺ with n = 3, 6, and 8 were studied and compared to the reaction rate of the N‐methyl‐4‐cyanopyridinium (MCP⁺). C₆bis(CP)²⁺ and C₈bis(CP)²⁺ obeyed the first‐order kinetic law. However for C₃bis(CP)²⁺ data fitted to a consecutive two‐step model reaction, the observed rate constants (k_obs) of C₈bis(CP)²⁺ and C₆bis(CP)²⁺ are approximately 50% and 100%, respectively, higher than those for MCP⁺, an effect mainly assigned to the higher charge density of these two derivatives. For C₃bis(CP)²⁺, the k_obs of the second (slow) step is almost twofold the value observed for C₆bis(CP)²⁺, whereas the first (fast) step is approximately six times higher. As for MCP, the hydrolysis of C_nbis(CP)²⁺ generates pyridone (P^o) and carbamidopyridinium (A⁺) units. For C₃bis(CP)²⁺, however at pHs above 11.5, one additional product is formed. From the existence of the new product and the kinetic evidence, a “sandwiched‐type” complex with the OH^? inserted between the rings is proposed. This structural effect in the C₃bis(CP)²⁺ due to the conformational effect justifies the (i) two kinetic steps, (ii) high rate constants, (iii) high P^o/A⁺ ratios, (iv) observed temperature and salt effects, and (v) the formation of the new product.