Rational design of 2D Janus P 3 m 1 M 2 N 3 (M = Cu, Zr, and Hf) and their surface-functionalized derivatives: ferromagnetic, piezoelectric, and photocatalytic properties.
Heng ZhangFrédéric GueganJunjie WangGilles FrapperPublished in: Physical chemistry chemical physics : PCCP (2024)
In this study, first-principles calculations were employed to rationally design two-dimensional (2D) Janus transition metal nitrides of P 3 m 1 M 2 N 3 phases, where M is a d-block element (Sc-Zn, Y-Cd, Hf-Hg). Among the 29 examined 2D M 2 N 3 , three 2D phases, namely P 3 m 1 Cu 2 N 3 , Zr 2 N 3 , and Hf 2 N 3 , exhibit excellent thermodynamic, dynamic, mechanical, and thermal stabilities. These novel Janus 2D materials exhibit ferromagnetic metallic and half-metallic behavior. The related 2D Janus surface-functionalized derivatives, Cu 2 N 3 H, Cu 2 N 3 F, Cu 2 N 3 Cl, Zr 2 N 3 H, Hf 2 N 3 H, and Hf 2 N 3 F, are all dynamically stable. The 2D Janus P 3 m 1 phases of Zr 2 N 3 H, Hf 2 N 3 H, and Hf 2 N 3 F, all with M in the +IV oxidation state, act as semiconductors in the visible region, with energy band gaps of 2.26-2.70 eV at the HSE06 level of theory. On the other hand, the 2D Janus P 3 m 1 Cu 2 N 3 X phases (where X = H, F, and Cl) are ferromagnetic half-metals. Additionally, it has been unveiled that there are high hole mobilities (∼6 × 10 3 cm 2 V -1 s -1 ) derived from the moderate deformation potential and effective mass in the 2D Janus P 3 m 1 Zr 2 N 3 H, Hf 2 N 3 H, and Hf 2 N 3 F phases. Uniaxial strain engineering has demonstrated the outstanding in-plane piezoelectric properties of 2D Janus P 3 m 1 Zr 2 N 3 H, Hf 2 N 3 H, and Hf 2 N 3 F with high d 11 values (∼99.91 pm V -1 ). Furthermore, the desirable band-edge alignments and high anisotropic carrier mobilities of 2D Janus P 3 m 1 Zr 2 N 3 H, Hf 2 N 3 H, and Hf 2 N 3 F phases indicate their potential as visible light-driven photocatalysts for water splitting reactions on different facets. These properties render 2D Janus P 3 m 1 Zr 2 N 3 H, Hf 2 N 3 H, and Hf 2 N 3 F phases promising for use in optoelectronics, piezoelectric sensing, and photocatalysis applications.