Download This PaperThe Defective C3n Monolayers as High-Efficient Hydrogen Purification Membranes: Dft Calculations and Md Simulations
31 Pages Posted: 30 Sep 2023
Abstract
The design of new high-performance membranes for separation and purification of hydrogen remains highly desirable for industrial applications. Herein, using the density functional theory calculations along with MD simulations, we demonstrated firstly a new 2D membrane based C3N monolayer (D-C3N) with intrinsic pores and then investigated its potential as gas separation membranes for H2 purification. The cohesive energy and ab initio MD simulations confirmed that the D-C3N monolayer is structurally and thermodynamically stable under 1800 K. All considered gas molecules are physisorbed on the D-C3N monolayer with small interaction energy. At room temperature, the D-C3N membrane for H2 gas has high selectivity over other gases such as 1.5×103, 1.8×105, 8.8×109, 1.4×1012, and 1.3×1019 for H2/N2, H2/CO2, H2/O2, H2/H2O, and H2/CH4 at 300 K, respectively, and the H2 permeance is as high as 2.2×10-5 mol·m-2·s-1·Pa-1, exceeding the industrially acceptable value and most of the carbon-based separation membranes. In addition, MD simulations further confirmed that the defective porous C3N monolayer has ideal selectivity and permeation as a promising separation membrane for H2 purification from other gases for industrial applications.
Keywords: Defective C3N membrane, hydrogen purification, Selectivity and permeance, DFT calculations, MD simulations
Suggested Citation: Suggested Citation