TOPOLOGICAL ANALYSIS OF THE ELECTROSTATIC POTENTIAL in MOLECULAR SYSTEMS

Enrique Espinosa

Université de Lorraine, CNRS, CRM2 (Laboratoire de Cristallographie, Résonance Magnétique et Modélisations), UMR 7036, F-54000 Nancy (France)

E-mail: enrique.espinosa@univ-lorraine.fr

The molecular electrostatic potential j(r) has been extensively used in the analysis of molecular recognition due to the electrostatic character of long-range interactions. In most cases, relevant features of j(r) are found in the outer molecular envelop, pointing its nucleophilic and electrophilic regions.

The topological analysis of j(r) has been developed in order to further exploit the information contained in this function. The gradient vector field of j(r) leads to a complete partition of the molecular space in disjoint regions, which are separated by zero-flux surfaces of the scalar field j(r). These surfaces define electrostatic basins, which are different from those obtained from the topological analysis of the electron density distribution r(r), called atomic basins. A most significant consequence of electrostatic basins enclosed by zero-flux surfaces of j(r) is that they define the regions of the real space with zero net charge. Additionally, the gradient function of j(r), which is the negative of the electric field (Ñj(r) = -e(r)), draws the force lines in the real space stablishing molecular communication.

In the first part of the talk we will see how the electric field lines are able to determine without ambiguity the true electrophilic and nucleophilic sites in molecules, and how they can accurately show the extension and shape of their influence zones in the space out of molecules (neutral, negatively and positively charged).

In the second part of the talk we will introduce the intersection of the gradient vector fields of j(r) and r(r). We will see how the particular positioning of their zero flux surfaces divide bonding regions in three parts, the central one (called electrostatic attraction region (EAR)) being involved in the main contribution to the electrostatic interaction. This topological and electrostatic description has permitted to understand, and to explain, the paradoxical situation of anion-anion and cation-cation aggregates, which will be presented in the lecture.

References

 “Zero-flux surfaces of the electrostatic potential: The border of influence zones of nucleophilic and electrophilic sites in crystalline environment”, I. Mata, E. Molins, E. Espinosa, J. Phys. Chem. A, 2007, 111, 39, 9859-9870

“Topological properties of the electrostatic potential in weak and moderate N…H hydrogen bonds”, I. Mata, E. Molins, I. Alkorta, E. Espinosa, J. Phys. Chem. A, 2007, 111, 28, 6425-6433

“Electrostatics at the Origin of the Stability of Phosphate-Phosphate Complexes Locked by Hydrogen Bonds”, I. Mata, I. Alkorta, E. Molins, E. Espinosa, ChemPhysChem, 2012, 13, 6, 1421-1424

“Tracing environment effects that influence the stability of anion-anion complexes: The case of phosphate-phosphate interactions”, I. Mata, I. Alkorta, E. Molins, E. Espinosa, Chem. Phys. Lett., 2013, 555, 106-109

“The Paradox of Hydrogen-Bonded Anion Anion Aggregates in Oxoanions: A Fundamental Electrostatic Problem Explained in Terms of Electrophilic…Nucleophilic Interactions”, I. Mata, E. Molins, I. Alkorta, E. Espinosa, J. Phys. Chem. A, 2015, 119, 1, 183-194

“Charged versus Neutral Hydrogen-Bonded Complexes: Is There a Difference in the Nature of the Hydrogen Bonds?”, I. Alkorta, I. Mata, E. Molins, and E. Espinosa, Chem. Eur. J., 2016, 22, 9226 – 9234.

“Energetic, Topological and Electric Field Analyses of Cation-Cation Nucleic Acid Interactions in Watson-Crick Disposition”, I. Alkorta, I. Mata, E. Molins and E. Espinosa

ChemPhysChem, 2019, 20, 148-158