Hydrogen Absorption Properties of Metal-Ethylene Complexes

TL;DR

This study explores various metal-ethylene complexes, especially with lithium, demonstrating their high hydrogen absorption capacities and stability, indicating potential for efficient hydrogen storage materials.

Contribution

It extends previous work by analyzing a broader range of metals and structures, revealing lithium-ethylene complexes with record hydrogen storage capacity and stability up to 500 K.

Findings

Li-ethylene complexes can absorb up to 16 wt % hydrogen.

Structures are stable up to 500 K based on phonon and MD simulations.

Reaction barriers suggest feasible transformations without losing hydrogen capacity.

Abstract

Recently, we have predicted [Phys. Rev. Lett. 97, 226102 (2006)] that a single ethylene molecule can form stable complexes with light transition metals (TM) such as Ti and the resulting TMn-ethylene complex can absorb up to ~12 and 14 wt % hydrogen for n=1 and 2, respectively. Here we extend this study to include a large number of other metals and different isomeric structures. We obtained interesting results for light metals such as Li. The ethylene molecule is able to complex with two Li atoms with a binding energy of 0.7 eV/Li which then binds up to two H2 molecules per Li with a binding energy of 0.24 eV/H2 and absorption capacity of 16 wt %, a record high value reported so far. The stability of the proposed metal-ethylene complexes was tested by extensive calculations such as normal-mode analysis, finite temperature first-principles molecular dynamics (MD) simulations, and reaction path calculations. The phonon and MD simulations indicate that the proposed structures are stable up to 500 K. The reaction path calculations indicate about 1 eV activation barrier for the TM2-ethylene complex to transform into a possible lower energy configuration where the ethylene molecule is dissociated. Importantly, no matter which isometric configuration the TM2-ethylene complex possesses, the TM atoms are able to bind multiple hydrogen molecules with suitable binding energy for room temperature storage. These results suggest that co-deposition of ethylene with a suitable precursor of TM or Li into nanopores of light-weight host materials may be a very promising route to discovering new materials with high-capacity hydrogen absorption properties.