OxH2x+1+ Clusters: A New Series of Non-Metallic Superalkali Cations by Trapping H3O+ into Water
Ambrish Kumar Srivastava

TL;DR
This study introduces a new series of non-metallic superalkali cations, OxH2x+1+, created by trapping H3O+ in water, revealing their stability and decreasing electron affinity, with potential for novel applications.
Contribution
The paper reports the design and characterization of a novel series of non-metallic superalkali cations, expanding the understanding of superalkali properties beyond metallic clusters.
Findings
OxH2x+1+ clusters are stable against deprotonation and dehydration.
Their electron affinities decrease with increasing x, indicating superalkali behavior.
The series can be extended to even lower electron affinities, approaching 1.85 eV.
Abstract
The term superalkali refers to the clusters with lower ionization energy than alkali atoms. Typical superalkali cations include a central electronegative core with excess metal ligands, OLi3+, for instance, which mimic the properties of alkali metal ions. We report a new series of non-metallic superalkali cations, OxH2x+1+ (x = 1-5) using ab initio MP2/6-311++G(d,p) level. These cations are designed by successive replacement of H-ligands of hydronium cation (OH3+) by ammonium (OH3) moieties followed by their geometry optimization. The resulting OxH2x+1 + clusters, which can be expressed in the form of OH3 + (x-1)H2O complexes, possess a number of electrostatic as well as partially covalent H-bonds, with the interacting energy in the range 5.2-29.3 kcal/mol as revealed by quantum theory of atoms in molecules analyses. These cations are found to be stable against deprotonation as well as…
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Taxonomy
TopicsInorganic Fluorides and Related Compounds · Advanced Chemical Physics Studies · Inorganic Chemistry and Materials
