مرکز منطقه ای اطلاع رساني علوم و فناوري - Materials limitations of amorphous-Si:H transistors

Abstract :

Application of two-terminal (back-to-back diode) and three-terminal (FET) amorphous-Si:H devices to the matrix addressing of liquid-crystal displays (LCD) is discussed. a-Si:H back-to-back diodes appear to be suitable switching elements for displays of intermediate complexity. These devices are easy to fabricate and appear to have a high yield. A n analysis of matrix-addressed LCD\´s shows that FET\´s implemented in a low-mobility material, such as a-Si:H, are best suited for (medium) high-resolution capacitorless displays where competing technologies (CdSe, poly-Si) are likely to encounter difficulties in meeting the off requirements. Instabilities in a-Si:H-based devices were studied by fabricating inverted and noninverted FET\´s with a variety of gate dielectrics: SiO2, both thermally grown and sputtered; Si3N4, both by GD and LPCVD; and evaporated SiOx. Comparison of these devices, which are listed in decreasing order of stability, showed that a-Si:H FET\´s with thermal oxide were stable. In other devices, the decrease of the source-drain current ISDwith time was mainly caused by trapping at the semiconductor-dielectric interface. Feasibility of a-Si:H FET-addressed LCD\´s was studied by fabricating experimental 26 × 26 G-H LCD\´s by photolithographic methods on soda-lime glass substrates, using either GD Si3N4or sputtered SiO2as a gate dielectric. FET\´s use a ring layout for the gate geometry to maximize the off resistance and a positive photoconductivity-feedback mechanism to maximize the on current and to minimize cumulative trapping. The Schottky contact inverted FET\´s ( $L = 25$ µm; $W = 3800$ µm) have a switching range > 10⁶. In dc conditions, at a source-drain voltage $V_{SD} = 10$ V, the drain current ISDis typical < 1 pA at a gate voltage $V_{G} = 0$ and > 1 µA at $V_{G} = 10$ V. The transistor characteristics are time dependent. The channel mobility, as derived from the linear (triode) regime is about µeff= 0\´02 cm²/V . s at quasi-dc and increases wit- h decreasing pulse length until it saturates at µeff= 0.2 cm²/V . s. ISDdecreases with time to about $frac{1}{2}$ to $frac{1}{3}$ of its initial value in ambient light (operating devices) and to about $frac{1}{10}$ in the dark, mostly due to trapping in the gate dielectric. The time-dependent decrease in ISDhas been studied under dc conditions for the plasma-deposited SiO2and Si3N4gate insulators and under pulse conditions for Si3N4. Auger depth-profile analysis shows that the properties of amorphous hydrogenated silicon FET\´s are not very sensitive to the incorporation of common residual gases (O2, N2). Lifetime tests at room temperature and at 80°C for > 1 year have been carried out and the displays appear to be stable.