Ab initio screening of refractory nitrides and carbides for high temperature hydrogen permeation barriers

Density functional theory was used to screen eleven refractory materials - two pure metals, six nitrides, and three carbides-as high-temperature hydrogen permeation barriers to prevent hydrogen embrittle-ment. Activation energies were calculated for atomic hydrogen (H) diffusion into the first subsurface layer from the lowest energy surface of the high-temperature phase of each candidate material. The candidate barrier materials with the highest activation energies are h-BN, c-BN, HfN, and ZrN with predicted barri-ers of 3.25 eV, 3.23 eV, 3.14 eV, and 2.76 eV, respectively. Strain energies, Bader charges, and density of states were calculated for the diffusing H at the relaxed initial state and the transition state to provide insight into contributing factors to high energy barriers. The diffusing H atom in materials with the high -est predicted barriers are protic. In addition, interstitial H atoms induce mid-gap states in the density of states of both BN polymorphs. The nitrogen retention of each nitride material at high temperatures was predicted using nitrogen vacancy formation energies with respect to gaseous nitrogen. Experimental eval-uation of nitrogen retention in h-BN, ZrN, and TiN confirmed their resistance to nitrogen loss at 1773 K. However, of these nitrides, TiN is predicted to be the least stable. This work identifies multiple promising materials that are predicted to be effective hydrogen barriers at high temperatures and that are stable at temperatures above 2700 K, with BN predicted to perform best.(c) 2022 Elsevier B.V. All rights reserved.

Automated summary

Density functional theory was used to screen refractory materials as high-temperature hydrogen permeation barriers. The study calculated activation energies and analyzed the properties of diffusing hydrogen atoms in the materials. Experimental evaluation confirmed the resistance of some nitride materials to nitrogen loss at high temperatures. This research provides theoretical support for effective hydrogen barriers at high temperatures.