Characterization of nitrogen doped p-type ZnO thin films prepared by reactive ion beam sputter deposition

Abstract Nitrogen doped ZnO (ZnO:N) thin films have been successfully prepared by reactive ion beam sputter deposition. The ZnO:N thin films show a preferred growth orientation along the (002) direction regardless of nitrogen flow rates. Raman spectroscopy analysis shows nitrogen related local vibration modes at 275 and 576 cm − 1 in addition to the ZnO E 2 (high) mode at 436 cm − 1 , indicating a successful incorporation of nitrogen into the ZnO. Both of the peak intensities of 275 and 576 cm − 1 reach a maximum after post-growth annealing at 500 °C. ZnO:N deposited with a 0.5 sccm nitrogen flow rate exhibits p -type conductivity with a hole concentration of 2.1 × 10 17 /cm 3 and a mobility of 3 cm 2 V − 1  s − 1 after annealing at 500 °C. Conversion to p -type conductivity was not observed on ZnO:N deposited with higher nitrogen flow rates. The p -type conductivity remains stable after it was stored at ambient conditions for more than two months. The p -type ZnO:N thin film is transparent in the visible range with a transmittance larger than 83%. SIMS analysis indicates that nitrogen concentration of less than 1.2 at.% results in the successful preparation of p -type ZnO:N. ZnO:N deposited with higher nitrogen concentration results in n -type conductivity which is likely due to the formation of molecular nitrogen replacing oxygen sites that act as double donors (N 2 ) O .

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