Thin-film, self-aligned source-gated transistors (SGTs) have been made in polysilicon.The very high output impedance of this type of transistor makes it suited to analog circuits.Intrinsic voltage gains of greater than one thousand have been measured at particular drain voltages. The drain voltage dependence of the gain is explained based on the device physics of the source-gated transistor and the fact that pinch-off occurs at both the source and the drain. The results obtained from these devices, which are far from optimal, suggest that, with proper design, the source-gated transistor is well suited to a wide range of analog applications.
Ultra-large-scale integrated (ULSI) circuits have benefited from successive refinements in device architecture for enormous improvements in speed, power efficiency and areal density. In large-area electronics (LAE), however, the basic building-block, the thin-film field-effect transistor (TFT) has largely remained static. Now, a device concept with fundamentally different operation, the source-gated transistor (SGT) opens the possibility of unprecedented functionality in future low-cost LAE. With its simple structure and operational characteristics of low saturation voltage, stability under electrical stress and large intrinsic gain, the SGT is ideally suited for LAE analog applications. Here, we show using measurements on polysilicon devices that these characteristics lead to substantial improvements in gain, noise margin, power-delay product and overall circuit robustness in digital SGT-based designs. These findings have far-reaching consequences, as LAE will form the technological basis for a variety of future developments in the biomedical, civil engineering, remote sensing, artificial skin areas, as well as wearable and ubiquitous computing, or lightweight applications for space exploration.
-Source-gated transistors (SGTs) have potentially very high output impedance and low saturation voltages, which make them ideal as building blocks for high performance analog circuits fabricated in thin-film technologies. The quality of the saturation is greatly influenced by the design of the field-relief structure incorporated into the source electrode. Starting from measurements on self-aligned polysilicon structures, we show through numerical simulations how the field plate design can be improved. A simple source field plate around 1µm long situated several tens of nm above the semiconductor can increase the low-voltage intrinsic gain by more than two orders of magnitude and offers adequate tolerance to process variations in a moderately scaled thin-film SGT.
Hot carrier instabilities in poly-Si thin film transistors (TFTs) are caused by high electric fields at the drain. These high fields are determined mainly by the abruptness of the lateral n+ doping profile in the drain and the two-dimensional (2D) coupling of the x and y components of the electric field between the gate and drain. The density of trapping states in the poly-Si film, however, has a much less significant impact on the field. Further, it is shown that improving the properties of the poly-Si film tends to have an adverse affect on hot carrier stability. Consequently, it is concluded that drain field relief is essential for hot carrier stability of n-channel poly-Si TFTs. It is shown that gate overlapped lightly doped drain (GOLDD) architectures can be used to relieve the drain field without introducing series resistance. Stable TFTs have been fabricated with GOLDD, consistent with circuit operation up to drain biases of 20 V. GOLDD is also effective in reducing the field enhanced leakage current in the off-state.
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