Abstract: The present invention relates to a transistor comprising a gate channel area and a gate stack having mechanical stress arranged on the gate channel area.

Abstract: The present invention relates to a transistor comprising a gate channel area and a gate stack having mechanical stress arranged on the gate channel area.

Abstract: A method of forming hemispherical silicon-germanium grains within a capacitor which includes providing the semiconductor substrate and forming the capacitor surface in the substrate is provided. The method also includes forming a layer of grained silicon-germanium on the surface of the capacitor. Another aspect of the present invention is seen in a capacitor formed in the substrate of a semiconductor device. A trench is formed in the substrate having a surface and a first capacitor electrode is formed in the semiconductor substrate around the trench. A layer of grained silicon-germanium is formed on the surface of the trench. A dielectric layer is formed on the grained silicon-germanium layer and a second capacitor electrode is formed on the dielectric layer.

Abstract: The present invention provides a fabrication method for a semiconductor structure having the steps of providing a semiconductor substrate (1); providing and patterning a silicon nitride layer (3) on the semiconductor substrate (1) as topmost layer of a trench etching mask; forming a trench (5) in a first etching step by means of the trench etching mask; conformally depositing a liner layer (10) made of silicon oxide above the resulting structure, which leaves a gap (SP) reaching into the depth in the trench (5); carrying out a V plasma etching step for forming a V profile of the line layer (10) in the trench (5); wherein the liner layer (10) is pulled back to below the top side of the silicon nitride layer (3); an etching gas mixture comprises C5F8, O2 and an inert gas is used in the V plasma etching step; the ratio (V) of C5F8/O2 lies between 2.5 and 3.5; and the selectivity of the V plasma etching step between silicon oxide and silicon nitride is at least 10.

Abstract: The present invention provides methods of producing substantially void-free trench structures. After deposition of an a-Si or polysilicon layer in a trench formed in a semiconductor, the a-Si or polysilicon is exposed to hydrogen at an elevated temperature.

Abstract: A method of filling high ratio trenches on a substrate is described. First, an oxidizable layer is deposited on the substrate. Thereafter, a trench fill oxide is deposited on the substrate and on the oxidizable layer. Afterwards, the resulting structure is annealed using an oxygen containing gas such that the oxidizable layer is oxidized.

Abstract: The present invention provides methods of producing substantially void-free trench structures. After deposition of an a-Si or polysilicon layer in a trench formed in a semiconductor, the a-Si or polysilicon is exposed to hydrogen at an elevated temperature.

Abstract: The present invention provides a fabrication method for a semiconductor structure having the steps of providing a semiconductor substrate (1); providing and patterning a silicon nitride layer (3) on the semiconductor substrate (1) as topmost layer of a trench etching mask; forming a trench (5) in a first etching step by means of the trench etching mask; conformally depositing a liner layer (10) made of silicon oxide above the resulting structure, which leaves a gap (SP) reaching into the depth in the trench (5); carrying out a V plasma etching step for forming a V profile of the line layer (10) in the trench (5); wherein the liner layer (10) is pulled back to below the top side of the silicon nitride layer (3); an etching gas mixture comprises C5F8, O2 and an inert gas is used in the V plasma etching step; the ratio (V) of C5F8/O2 lies between 2.5 and 3.5; and the selectivity of the V plasma etching step between silicon oxide and silicon nitride is at least 10.

Abstract: The present invention related to doping of amorphous silicon and polysilicon in trench structures for semiconductor devices. A single gas phase doping step is performed after a thin layer of amorphous silicon or polysilicon is deposited in the trench. The gas phase doping occurs at elevated temperature and moderate pressure to yield a dopant concentration on the order of 1×1020 atoms/cm3.

Abstract: A trench capacitor is formed with an insulation collar. After the formation of the trench, firstly an insulating layer is deposited, from which layer the insulation collar will be subsequently formed. Afterward, the trench is partly filled with a sacrificial filling material and a thin patterning layer is deposited thereon. Spacers are formed from that layer and cover the insulating layer in the upper region of the trench. Afterward, the sacrificial filling material and the insulating layer are completely removed in the lower region of the trench. As a result, the insulation collar is produced in the upper region of the trench.

Abstract: A method for improving a doping profile using gas phase doping is described. In the method, silicon nitride and/or products of decomposition from a silicon nitride deposition are introduced in a process chamber before or during the actual gas phase doping. This allows the doping profile to be significantly improved.

Abstract: A method for manufacturing a trench capacitor uses a low-pressure gas phase doping for forming a buried plate as a capacitor plate. The use of the low-pressure gas phase doping reduces process costs and improves capacitor properties.

Abstract: A method for improving a doping profile using gas phase doping is described. In the method, silicon nitride and/or products of decomposition from a silicon nitride deposition are introduced in a process chamber before or during the actual gas phase doping. This allows the doping profile to be significantly improved.

Abstract: A trench capacitor is formed with an insulation collar. After the formation of the trench, firstly an insulating layer is deposited, from which layer the insulation collar will be subsequently formed. Afterward, the trench is partly filled with a sacrificial filling material and a thin patterning layer is deposited thereon. Spacers are formed from that layer and cover the insulating layer in the upper region of the trench. Afterward, the sacrificial filling material and the insulating layer are completely removed in the lower region of the trench. As a result, the insulation collar is produced in the upper region of the trench.

Abstract: A method for manufacturing a trench capacitor uses a low-pressure gas phase doping for forming a buried plate as a capacitor plate. The use of the low-pressure gas phase doping reduces process costs and improves capacitor properties.