First-Principles Investigation of X2NiH6 (X = Ca, Sr, Ba) Hydrides for Hydrogen Storage Applications

TL;DR

This study uses first-principles calculations to analyze the thermodynamic, optical, mechanical, and hydrogen storage properties of X2NiH6 (X = Ca, Sr, Ba) hydrides, identifying Ca2NiH6 as the most promising for storage applications.

Contribution

It provides a comprehensive first-principles analysis of X2NiH6 hydrides, highlighting their stability, optical, mechanical, and storage properties, and identifies Ca2NiH6 as the best candidate for hydrogen storage.

Findings

Ca2NiH6 has the highest hydrogen storage capacity (4.005 wt%).

Ba2NiH6 exhibits high refractive index at low energies.

Sr2NiH6 is mechanically incompressible and moderately malleable.

Abstract

First-principles DFT calculations on the hydrides Ca2NiH6, Sr2NiH6, and Ba2NiH6 reveal key thermodynamic properties. These compounds exhibit increasing entropy and heat capacity with temperature, and are thermodynamically stable at elevated temperatures due to negative free energies. The kinetics of hydrogen storage is influenced by entropy changes during hydrogen adsorption and desorption. Optically, Ba2NiH6 shows a high refractive index at low energies. Mechanical assessments indicate Sr2NiH6 is incompressible with moderate malleability, Ca2NiH6 has the highest resistance to deformation, while Ba2NiH6 is most compressible. Formation energies and hydrogen storage capacities (4.005 wt% for Ca2NiH6, 2.548 wt% for Sr2NiH6, and 1.750 wt% for Ba2NiH6) highlight Ca2NiH6 as the most promising candidate for hydrogen storage technology.