While it is well established that the dominant degradation mechanism for the chemical warfare agent, sarin, is hydrolysis via an S(N)2 mechanism in aqueous environments, the same cannot be said when hydrophilic or hydrophobic surfaces are present. Utilizing first-principles molecular dynamics simulations based on density functional theory, potential degradation pathways for sarin were investigated in the vicinity of both hydrophilic and hydrophobic surfaces. In an idealized situation where sarin is within hydrogen-bonding distance to a hydrophilic surface, the most probable degradation occurred via an S(N)2 mechanism, but with a lowering of the reaction barrier (Delta Delta G double dagger) of similar to 15 kcal/mol as compared with bulk aqueous S(N)2 decomposition. However, in the presence of an idealized hydrophobic surface, it was found that the degradation mechanism for sarin proceeded via an S(N)1-type mechanism where the phosphorus-fluorine bond breaks first, followed by a second step in which water acts as a nucleophile. The reaction barrier associated with such a reaction is similar to 10 kcal/mol higher than the S(N)2 degradation path found in bulk aqueous environments. The results found here clearly demonstrate how surfaces can significantly alter sarin decomposition.

• 出版日期2012-5-3