Hydrogen separation membranes are a critical component
in the emerging
hydrogen economy, offering an energy-efficient solution for the purification
and production of hydrogen gas. Inspired by the recent discovery of
monolayer covalent fullerene networks, here we show from concentration-gradient-driven
molecular dynamics that quasi-square-latticed monolayer fullerene
membranes provide the best pore size match, a unique funnel-shaped
pore, and entropic selectivity. The integration of these attributes
renders these membranes promising for separating H2 from
larger gases such as CO2 and O2. The ultrathin
membranes exhibit excellent hydrogen permeance as well as high selectivity
for H2/CO2 and H2/O2 separations,
surpassing the 2008 Robeson upper bounds by a large margin. The present
work points toward a promising direction of using monolayer fullerene
networks as membranes for high-permeance, selective hydrogen separation
for processes such as water splitting.