2021-03-232014-01-011472797818758983SCOPUS;2-s2.0-84900413482http://hdl.handle.net/10784/27155A detailed study of the interactions leading to stabilization of the NH3(H2O){n =1,2} clusters is presented in this work. The Potential Energy Surface for the trimers was explored using an adapted version of the simulated annealing optimization procedure that produced cluster candidate structures that were further optimized, refined, and characterized at the MP2/6-311++G(d, p) level. Our results indicate that hydrogen bonding of the N-H type is stronger and more covalent than of the O-H type. We provide evidence that suggests that the topological complexity of the electron distributions is directly correlated with cluster stability and that most of the stabilization energy originates in electrostatic and exchange contributions. Our calculated trimerization enthalpy, H° 298-41.75 kJ/mol, is in excellent agreement with the experimental enthalpy of adsorption of NH3 into surface water, reported to be-(41 ± 5) kJ/mol. © 2014-IOS Press.enghttps://v2.sherpa.ac.uk/id/publication/issn/1472-7978articleEnthalpyHydrogen bondsPhysical chemistryQuantum chemistrySimulated annealingAIM analysisAmmonia/waterElectron distributionsEnthalpy of adsorptionSimulated annealing optimizationStabilization energyStochastic optimizationsTopological complexityStabilization2021-03-23Guerra, D.David, J.Restrepo, A.10.3233/JCM-140487