Abstract: The invention relates to a field effect transistor in which the planar channel region on the upper surface of the elevation is extended in width by means of additional vertical channel regions on the lateral surfaces of the elevation. Said additional vertical channel regions connect directly to the planar channel region (vertical extended channel regions). Said field effect transistor has the advantage that a significant increase in the effective channel width for the current flow ION can be guaranteed relative to conventional transistor structures used up until the present, without having to accept a reduction in the achievable integration density. Said field effect transistor furthermore has a low reverse current IOFF. The above advantages are achieved without the thickness of the gate insulators up to the region of the charge transfer tunnels having to be reduced or a reduced stability.

Abstract: Process for producing a plurality of gate stacks approximately the same height and equidistant on a semiconductor substrate. The process includes providing a gate dielectric on the semiconductor substrate and applying and patterning at least a first layer and a second layer, above the first layer, to the gate dielectric to produce the gate stacks. An oblique implantation of an oxidation-inhibiting implantation species is carried out into two opposite, uncovered side faces of the second of the gate stacks, with respectively adjacent gate stacks serving to shadow the uncovered side faces of the first layer of the gate stacks. Oxidation to simultaneously form a first oxide layer on uncovered side faces of the first layer of the gate stacks and a second oxide layer on uncovered side faces of the second layer of the gate stacks is carried out, the thickness of the first oxide layer being greater than the thickness of the second oxide layer.

Abstract: A memory cell includes a selection transistor and a trench capacitor. The trench capacitor is filled with a conductive trench filling, on which an insulating covering layer is arranged. The insulating covering layer is laterally overgrown, proceeding from the substrate, with a selectively grown epitaxial layer. The selection transistor is formed in the selectively grown epitaxial layer, comprises a source region connected to the trench capacitor, and a drain region connected to a bit line. The junction depth of the source region is now chosen so that the source region reaches as far as the insulating covering layer. Optionally, the thickness of the epitaxial layer can be reduced to a thickness by oxidation and a subsequent etching. Afterwards, a contact trench is etched through the source region down to the conductive trench filling, which trench is filled with a conductive contact and electrically connects the conductive trench filling to the source region.

Abstract: The method for producing a shallow trench isolation for n- and p-channel field-effect transistors in a semiconductor module provides the following steps. A thermal oxide layer is applied in isolation trenches. A nitride liner is subsequently applied. In a further step, a mask is applied in the region in which n-channel field-effect transistors are intended to be produced. The nitride liner is removed around the mask. Finally, the mask is also removed. As a result, the properties of the n-channel field-effect transistors are improved, without impairing the properties of the p-channel field-effect transistors.

Abstract: A method for the fabrication of an integrated semiconductor component, in which at least one isolation trench is formed, a first layer of a nonconductive material is applied by a nonconformal deposition method, and a second layer of a nonconductive material is applied by a conformal deposition method at least to the back surface of the semiconductor component.

Abstract: The method for producing a shallow trench isolation for n- and p-channel field-effect transistors in a semiconductor module provides the following steps. A thermal oxide layer is applied in isolation trenches. A nitride liner is subsequently applied. In a further step, a mask is applied in the region in which n-channel field-effect transistors are intended to be produced. The nitride liner is removed around the mask. Finally, the mask is also removed. As a result, the properties of the n-channel field-effect transistors are improved, without impairing the properties of the p-channel field-effect transistors.

Abstract: A description is given of a method for a selective masking of a structure with a small structure surface with respect to a structure with a larger structure surface. To that end, the structures are filled with a covering layer. The covering layer is formed with a larger thickness above the first structure, which has the larger structure surface, than above the second structure. Afterward, the covering layer is removed by a homogeneous removal method, so that first the structure surface of the second structure is uncovered. A simple self-aligning method for fabricating a mask for uncovering the second structure is thus provided.

Abstract: A method for filling an isolation trench in a semiconductor substrate includes the steps of forming a first silicon oxide layer on sidewalls and the floor of each trench by an oxidation step, forming a second silicon oxide layer on the sidewalls and floor of the trench by a first high-density plasma-chemical vapor deposition process without applying an RF voltage to a wafer so that the ratio of depositing to etching is extremely high and then forming a third silicon oxide layer by a second high-density plasma-chemical vapor deposition process having an RF voltage applied to the wafer so that the ratio of depositing to etching is much lower than in the first-mentioned process.

Abstract: The instant invention is a method for fabricating a trench contact to a deep trench capacitor with a polysilicon filling in a trench hole formed in a silicon substrate. An epitaxy process is performed to selectively grow silicon above the polysilicon filling in the trench hole. An opening leading to the polysilicon filling is anisotropically etched into the epitaxially grown silicon. The opening has lateral dimensions that are smaller than those of the polysilicon filling, and the opening is filled with polysilicon.