Construction of ZnO/GaN in-plane heterojunction with different contacted modes and vacancy defects for improving magnetic and adsorption properties

ZnO/GaN in-plane heterojunction with three contacted modes (Zn-N, Ga-O and both Zn-N and Ga-O, named He₁, He₂ and He₃, respectively) is constructed. At the same time, the vacancy defects (V_Zn, V_N, V_Ga and V_O) are introduced at the interface of the in-plane heterojunction. Their electric, magnetic and adsorption properties with vacancy defects are analyzed based on density function theory (DFT). After constructing the heterojunction, the effective mass of holes obviously increases and leads to higher separation efficiency between electrons and holes. Band structures show that V_Zn and V_Ga change the magnetism of He₃ and total magnetic moment (M) are 1.69 μ_B and 2.73 μ_B, respectively. He₃ exhibits semiconducting conductivity with V_Zn and semi-metallic conductivity with V_Ga. In order to explore the application in gas sensing field, the electric and adsorption characteristics of He₃ (with V_Zn and V_Ga) for CO₂, SO₂ and NO₂ gas molecules are combined to analysis. E_ad of the He₃ for SO₂ and NO₂ is higher than CO₂ adsorption. In addition, the magnetic properties of He₃ (with V_Zn and V_Ga) change drastically after adsorbing SO₂ and NO₂, which proves that He₃ is more sensitive to SO₂ and NO₂ than CO₂. These results demonstrate that He₃ not only exhibits unique electrical and magnetic properties, but also has potential applications in SO₂ and NO₂ gas sensors.