Abstract
Despite being a fundamental electronic component for over 70 years, it is still possible to develop different transistor designs, including the addition of a diode-like Schottky source electrode to thin-film transistors. The discovery of a dependence of the source barrier height on the semiconductor thickness and derivation of an analytical theory allow us to propose a design rule to achieve extremely high voltage gain, one of the most important figures of merit for a transistor. Using an oxide semiconductor, an intrinsic gain of 29,000 was obtained, which is orders of magnitude higher than a conventional Si transistor. These same devices demonstrate almost total immunity to negative bias illumination temperature stress, the foremost bottleneck to using oxide semiconductors in major applications, such as display drivers. Furthermore, devices fabricated with channel lengths down to 360 nm display no obvious short-channel effects, another critical factor for high-density integrated circuits and display applications. Finally, although the channel material of conventional transistors must be a semiconductor, by demonstrating a high-performance transistor with a semimetal-like indium tin oxide channel, the range and versatility of materials have been significantly broadened.
Highlights
The samples were annealed at 300 ◦C in N2 for 1 h before the deposition of the Pt Schottky contact
For the IGZO TFTs, Ti was used as source-drain contacts
Device simulations were carried out using Silvaco Atlas
Summary
NBITS is another long-standing barrier to the commercial application of oxide semiconductor TFTs [19, 20]. Exposure to a combination of near-bandgap illumination, negative bias, and elevated temperature, as would be expected in a display circuit, produces a negative shift in the turn-on voltage of IGZO TFTs. NBITS tests were carried out on our 20-nmthick IGZO SGTs. The devices were held at VG = −20 V and 60 ◦C under illumination from a 2,000-lx white LED. The high resistance of the source region will mask any channel instability.
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