Effects of Annealing Environments on the Solution-Grown, Aligned Aluminium-Doped Zinc Oxide Nanorod-Array-Based Ultraviolet Photoconductive Sensor

• Main Authors: Khalin, MIC (Author), Khusaimi, Z (Author), Mahmood, MR (Author), Mamat, MH (Author), Mohammad, NNHN (Author), Shariffudin, SS (Author), Sin, NDM (Author), Zahidi, MM (Author)
• Format: Article
• Language: English
• Series: JOURNAL OF NANOMATERIALS
• Online Access: View Fulltext in Publisher

 We have fabricated metal-semiconductor-metal-(MSM-) type ultraviolet (UV) photoconductive sensors using aluminium-(Al-) doped zinc oxide (ZnO) nanorod arrays that were annealed in different environments: air, oxygen, or a vacuum. The Al-doped ZnO nanorods had an average diameter of 60 nm with a thickness of approximately 600nm that included the seed layer (with thickness similar to 200 nm). Our results show that the vacuum-annealed nanorod-array-based UV photoconductive sensor has the highest photocurrent value of 2.43 x 10(-4) A. The high photocurrent is due to the high concentration of zinc (Zn) interstitials in the vacuum-annealed nanorod arrays. In contrast, the oxygen-annealing process applied to the Al-doped ZnO nanorod arrays produced highly sensitive UV photoconductive sensors, in which the sensitivity reached 55.6, due to the surface properties of the oxygen-annealed nanorods, which have a higher affinity for oxygen adsorption than the other samples and were thereby capable of reducing the sensor's dark current. In addition, the sensor fabricated using the oxygen-annealed nanorod arrays had the lowest rise and decay time constants. Our result shows that the annealing environment greatly affects the surface condition and properties of the Al-doped ZnO nanorod arrays, which influences the performance of the UV photoconductive sensors.