Exceedingly High Performance Top-Gate P-Type SnO Thin Film Transistor with a Nanometer Scale Channel Layer.
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ABSTRACT: Implementing high-performance n- and p-type thin-film transistors (TFTs) for monolithic three-dimensional (3D) integrated circuit (IC) and low-DC-power display is crucial. To achieve these goals, a top-gate transistor is preferred to a conventional bottom-gate structure. However, achieving high-performance top-gate p-TFT with good hole field-effect mobility (?FE) and large on-current/off-current (ION/IOFF) is challenging. In this report, coplanar top-gate nanosheet SnO p-TFT with high ?FE of 4.4 cm2/Vs, large ION/IOFF of 1.2 × 105, and sharp transistor's turn-on subthreshold slopes (SS) of 526 mV/decade were achieved simultaneously. Secondary ion mass spectrometry analysis revealed that the excellent device integrity was strongly related to process temperature, because the HfO2/SnO interface and related ?FE were degraded by Sn and Hf inter-diffusion at an elevated temperature due to weak Sn-O bond enthalpy. Oxygen content during process is also crucial because the hole-conductive p-type SnO channel is oxidized into oxygen-rich n-type SnO2 to demote the device performance. The hole ?FE, ION/IOFF, and SS values obtained in this study are the best-reported data to date for top-gate p-TFT device, thus facilitating the development of monolithic 3D ICs on the backend dielectric of IC chips.
SUBMITTER: Yen TJ
PROVIDER: S-EPMC7823917 | biostudies-literature | 2021 Jan
REPOSITORIES: biostudies-literature
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