High selectivity of N-doped ZnO nano-ribbons in detecting H₂, O₂ and CO₂ molecules: Effect of negative-differential resistance on gas-sensing

Adsorption and transport properties of ZnO nano-ribbons (ZnO-NRs) are investigated using density-functional theory (DFT) combined with non-equilibrium Green's-function (NEGF) formalism. Total-energy minimization shows the evidence for a selective chemisorption of three gases H₂, O₂ and CO₂ to take place when ZnO-NR is N-doped. The calculated IV characteristics of ZnO-NR:N based device shows a trend of negative differential resistance (NDR). The NDR behavior persists to exist in the ZnO-NR:N device after the chemisorption of oxidizing-gases O₂ and CO₂, as causing more charge depletion of N-site, more impedance, and a broadening of NDR range. However, the NDR trend disappears in the case of chemisorption of reduced-gas H₂, which donates charge to surface to rectify and enhance the conductance. The sensor responses, due to these three gases, are enormously large but yet with higher selectivity toward H₂ gas. Consequently, NDR-based devices are proposed for high sensitivity and selectivity toward, likely, a reduced-gas, such as H₂ in our present case. Our findings would be useful in exploring NDR to develop highly sensitive solid-state gas (ZnO-based) sensors of hydrogen and its related storage applications.