Abstract: A structure of a Trapezoid-Triple-Gate Field Effect Transistor (FET) includes a plurality of trapezoid pillars being transversely formed on an crystalline substrate or Silicon-On-Insulator (SOI) wafer. The trapezoid pillars can juxtapose with both ends connected each other. Each trapezoid pillar has a source, a channel region, and a drain aligned in longitudinal direction and a gate latitudinally superposes the channel region of the trapezoid pillar. The triple gate field effect transistor comprises a dielectric layer formed between the channel region and the conductive gate structure.

Abstract: A structure of a Trapezoid-Triple-Gate Field Effect Transistor (FET) includes a plurality of trapezoid pillars being transversely formed on an crystalline substrate or Silicon-On-Insulator (SOI) wafer. The trapezoid pillars can juxtapose with both ends connected each other. Each trapezoid pillar has a source, a channel region, and a drain aligned in longitudinal direction and a gate latitudinally superposes the channel region of the trapezoid pillar. The triple gate field effect transistor comprises a dielectric layer formed between the channel region and the conductive gate structure.

Abstract: The present invention discloses a method for forming a self-aligned silicidation of a metal oxide semiconductor. The feature of the present invention is to perform an ionic implanting step before carrying on the self-aligned silicidation. The implanted ion of the present invention, such as fluorine, chlorine, bromine, iodine, boron and trifluroborane, will react with the silicon on the surface of the gate structure and the silicon substrate and a barrier effect will be formed during silicidation. Therefore, a spike phenomenon because of the penetration of cobalt or the cobalt silicide into the gate structure or the source/drain regions is prevented. The junction leakage current and the breakdown voltage of the metal oxide semiconductor are avoided.

Abstract: The present invention discloses a method for forming a self-aligned silicidation of a metal oxide semiconductor. The feature of the present invention is to perform an ionic implanting step before carrying on the self-aligned silicidation. The implanted ion of the present invention, such as fluorine, chlorine, bromine, iodine, boron and trifluroborane, will react with the silicon on the surface of the gate structure and the silicon substrate and a barrier effect will be formed during silicidation. Therefore, a spike phenomenon because of the penetration of cobalt or the cobalt silicide into the gate structure or the source/drain regions is prevented. The junction leakage current and the breakdown voltage of the metal oxide semiconductor are avoided.

Abstract: A method of fabricating a self-aligned silicide (salicide). A gate and a source/drain region are formed in the substrate. An ion implantation process is performed to dope surfaces of the gate and the source/drain region with metal ions. A thermal process is performed to have the metal ions react with silicon in surfaces of the gate and the source/drain region, so as to form silicide layers on the gate and the source/drain region. The metal ions include cobalt ions, titanium ions, nickel ions, platinum ions and palladium ions.

Abstract: A method for manufacturing a photomask of cylindrical capacitor arrays surrounded by a corrugated protection trench is provided. First, a capacitor array layout is generated, next, the capacitor array patterns are copied to protection trench area with exact the same shape and pitch, finally, the protection trench is finished by filling connecting patterns between gaps of the capacitor arrays. A corrugated close loop protection trench pattern can hence be developed upon photoresist through the exposing and is developing of a photo stepper.

Abstract: A method for forming self-aligned contact (SAC) is disclosed to improve device reliability. The method includes forming a dielectric liner over the contact opening before the contact plug is filled in. Optional contact implantation before and after the liner formation can be added to enhance the doping profile of the device.

Abstract: The present invention discloses a mask reduction process to reduce the number of mask processes employed in the post-process of metal line formation. A fuse window opening can be formed together with the defining of contact holes. A pad opening can also be formed at the same time with the etching of a fuse window. With the process integration proposed in the present invention, a raised fuse and a fuse window with sidewall passivation can be formed.

Abstract: A method for controlling the thickness of a passivation layer underlying with a fuse on a semiconductor device is disclosed herein. The anti-reflective coating on a metal layer is buried in the passivation layer, and the fuse is in a semiconductor device. The method includes the following steps. First, use a first etchant and Ar to etch the passivation layer till the anti-reflective coating is exposed, the first thickness of the passivation layer above the anti-reflective coating is smaller than the second thickness of the passivation layer above the fuse. Then, utilize a second etchant to etch the anti-reflective coating till the metal layer is exposed. The second etchant has a selectivity ratio from the anti-reflective coating to the passivation layer being at least 10. The second etchant mentioned above includes BCl.sub.3, Cl.sub.2, O.sub.2, and Ar.

Abstract: The present invention provides a composite passivation film deposited at low temperatures (<150.degree. C.). A hydrogenated amorphous silicon nitride (a-SiN.sub.x :H) film is formed over a semiconductor device. Then a very thin layer (>6.4 nm) of an amorphous silicon hydrogen (a-Si:H) film is formed over the a-SiN.sub.x :H film. Such a composite passivation film can prevent semiconductor devices from oxidation due to percolation of moisture, and maintain the electric properties and stability of the semiconductor devices.