Single Boron Atom Anchored on graphitic carbon nitride nanosheet (B/g-C2N) as a photocatalyst for Nitrogen fixation: A First-Principles Study

Abstract

Photocatalytic nitrogen reduction is the promising way for ammonia production, the question now is that the search of highly active and low active catalysts. Based on the first-principles calculation, single boron atom is anchored on the g-C2N to form B/g-C2N, the results show that B/g-C2N can serve as a potential photocatalyst for N2 fixation. The introduction of B atom to g-C2N, the energy gap will reduce from 2.45 eV to 1.21 eV, and also show strong absorption in the visible light region. In addition, N2 can be efficiently reduced on B/g-C2N through the enzymatic mechanism with low onset potential of 0.07 V and rate-determing barrier of 0.50 eV. The "acceptance-donation" interaction between B/g-C2N and N2 plays a key role to active N2, the BN2 moiety of B/g-C2N acts as active and transportation center. And the activity originates from the strong interaction between 1π1π* orbitals of N2 and molecular orbitals of B/g-C2N, the ionization of 1π orbital and the filling of 1π* orbital can increase the N bond length greatly, making the activation of N2. Overall, this work demonstrates B/g-C2N is a promising photocatalyst for N2 fixation.