High-energy metal deposition significantly impacts the performance and reliability of two-dimensional (2D) semiconductors and nanodevices. This study investigates the localized annealing effect in atomically thin In2O3 induced during high-energy metal deposition. The localized heating effect alters the electronic performance of In2O3 devices, especially in shorter channel devices, where heat dissipation is further constrained. This effect creates a conductivity gradient along the In2O3 device with higher conductivity near the metal contact, as observed by conductive atomic force microscopy (C-AFM). This gradient leads to a pronounced threshold voltage (Vth) shift as the channel length (Lch) decreases, resembling a short-channel effect but one driven by thermal mechanisms rather than conventional mechanisms. Furthermore, metals with higher latent heats can exacerbate these effects. We also show that reversing the deposition sequence and postdeposition oxygen annealing effectively suppress Vth shifts across different Lch. This work offers key insights into controlling thermal effects during fabrication to improve ultrathin oxide transistor performance.
Keywords: high-energy metal deposition; indium oxide (In2O3); localized annealing; metal−semiconductor interface; negative contact resistance; threshold voltage; ultrathin oxide semiconductor.