Physical Review Research (Aug 2024)
Sodium chloride induced nitrogen salt with cyclo-N_{5} anions at high pressure
Abstract
The energy landscape of sodium chloride-nitrogen mixtures has been comprehensively explored to examine the ability of the formation of unknown compounds under pressures of up to 100 GPa, using swarm-intelligence structure prediction methodology and first-principles calculations. We identified a thermodynamically stable NaN_{5}ClN_{5} compound containing two cyclo-N_{5} species under pressures exceeding 53 GPa, representing milder conditions in comparison to those requisite for pure solid nitrogen. In NaN_{5}ClN_{5}, the high electron affinity of the cyclo-N_{5} motif allows it to oxidize the chlorine atoms, resulting in the formation of two cyclo-N_{5} anions. Additionally, the weak covalent interactions between Cl and nearby N atoms plays a key role in stabilization of structure. It has been demonstrated that simple NaN_{5} salt was a suitable precursor for the synthesis of NaN_{5}ClN_{5} at high pressure. Ab initio molecular dynamics simulations demonstrated the recoverability of NaN_{5}ClN_{5} as a metastable phase at ambient pressure-temperature conditions. Additionally, NaN_{5}ClN_{5} exhibits a higher energy density of 3.86 kJ/g and a lower mass density of 1.67 g/cm^{3} in comparison to metal pentazolate salts, highlighting its potential as a high energy-density material.
