Abstract: In a method for fabricating trench capacitors, in particular for memory cells having at least one selection transistor for integrated semiconductor memories, a trench for the trench capacitor is formed. The trench has a lower trench region, in which the capacitor is disposed, and an upper trench region, in which an electrically conductive connection from an electrode of the capacitor to a diffusion zone of the selection transistor is disposed. The method reduces the number of process steps for the fabrication of memory cells and enables fabrication of buried collars in the storage capacitors with an insulation quality as required for the fabrication of very large-scale integrated memory cells (<300 nm trench diameter).

Abstract: A structure on a layer surface of the semiconductor wafer has at least one first area region (8, 9), which is reflective for electromagnetic radiation, and at least one second, essentially nonreflecting area region (10, 11, 12). A light-transmissive insulation layer (13) and a light-sensitive layer are produced on said layer surface. The electromagnetic radiation is directed onto the light-sensitive layer with an angle ? of incidence and the structure of the layer surface is imaged with a lateral offset into the light-sensitive layer.

Abstract: In order to fabricate a semiconductor memory, a trench capacitor is arranged in a first trench. Beside the first trench, a first longitudinal trench and, parallel on the other side of the first trench, a second longitudinal trench are arranged in the substrate. A first spacer word line is arranged in the first longitudinal trench and a second spacer word line is arranged in the second longitudinal trench. There are arranged in the first trench connecting webs between the first spacer word line and the second spacer word line which have a thickness which, in the direction of the first spacer word line, is less than half the width of the first trench in the direction of the first spacer word line.

Abstract: To fabricate a trench capacitor in a substrate, a trench is formed in the substrate. The trench has an upper region and a lower region. In the trench, first of all nanocrystallites and/or a seed layer for nanocrystallites are deposited in the upper region and the lower region. Then, the nanocrystallites and/or the seed layer are removed from the upper region of the trench by means of an etching process. The etching parameters of the etching process are selected in such a way that the seed layer and/or the nanocrystallites which are uncovered in the upper region and the lower region are removed only from the upper region. Consequently, an expensive mask layer can be avoided in the lower region of the trench.

Abstract: A method for fabricating a semiconductor trench structure includes forming a trench in a semiconductor substrate and filling it with a filler. A first thermal process having a first maximum temperature cures the filler. Removing the filler from an upper region of the trench as far as a boundary surface defines a collar region. In a second thermal process having a second maximum temperature that is not significantly higher than the first maximum temperature, a liner is deposited on the collar region and the boundary surface. The liner is removed from the boundary surface, thereby exposing the filler. The filler is then removed from a lower region of the trench.

Abstract: A method for fabricating a trench capacitor with an insulation collar in a substrate, which is electrically connected to the substrate on one side via a buried contact, using a hard mask with a corresponding mask opening.

Abstract: A base body is provided, on which a first sealing ring and a second sealing ring are disposed. A substrate is disposed on the sealing rings in such a way that a cavity is formed between the first sealing ring, the second sealing ring, the base body and the substrate. An etching substance can be introduced into the cavity in order to etch clear a conductive layer that has been applied to the substrate. When a conductive layer that has been applied to the substrate back surface has been uncovered, an electrolyte can be introduced into the cavity, making contact with the conductive layer and therefore the substrate back surface.

Abstract: A semiconductor memory cell configuration includes dynamic memory cells respectively having a trench capacitor and a vertical selection transistor, the memory cells being disposed in matrix form, the trench capacitors and the associated vertical selection transistors following one another in each case in the form of rows and/or columns.

Abstract: A trench capacitor has a bottle-shaped trench in a semiconductor substrate. The bottle-shaped trench has a wider lower region and a narrower upper region. An outer electrode layer is formed in the semiconductor substrate around a lower section of the wider lower region of the trench. A dielectric intermediate layer is provided on the lower section of the trench wall in the wider lower region of the trench. A first, thick insulation layer, which adjoins the dielectric intermediate layer, is provided on an upper section of the trench wall in the wider lower region of the trench. A second, thin insulation layer, which adjoins the first thick insulation layer, is formed on the trench wall in the narrower upper region of the trench. An inner electrode layer substantially fills the trench. A method of producing a trench capacitor is also provided.

Abstract: A method for electrically contacting a rear side of a semiconductor substrate when processing the semiconductor substrate includes the step of placing the semiconductor substrate with a substrate rear side on a substrate holder such that an electrically conductive contact layer formed of a semiconductor material is disposed between the semiconductor substrate and the substrate holder.

Abstract: A trench capacitor has a first capacitor electrode, a second capacitor electrode, and a dielectric, which is arranged between the capacitor electrodes. The first capacitor electrode has a tube-like structure, which extends into a substrate. The second capacitor electrode includes a first section which is opposite to the internal side of the tube-like structure, with the dielectric arranged therebetween, and a second section, which is opposite to the external side of the tube-like structure with the dielectric arranged therebetween.

Abstract: In a SOI substrate, a semiconductor circuit formed in a SOI substrate, and an associated production method, a multilayer barrier layer with a potential barrier and a diffusion barrier is used to reliably prevent diffusion of impurities between element layers. This allows semiconductor circuits to be produced with smaller structure sizes and with a higher integration density.

Abstract: The integrated circuit configuration has at least one buried circuit element and an insulating layer. A multiplicity of insulating regions are in contact with one another to forming a locally delimited insulating layer in the substrate. In this way, trench capacitors implemented as buried circuit elements can be manufactured with a structure size of less than 100 nm in a simple and cost-effective manner.

Abstract: The integrated circuit configuration has at least one buried circuit element and an insulating layer. A multiplicity of insulating regions are in contact with one another to forming a locally delimited insulating layer in the substrate. In this way, trench capacitors implemented as buried circuit elements can be manufactured with a structure size of less than 100 nm in a simple and cost-effective manner.

Abstract: A method for fabricating a trench capacitor, that includes steps of: providing a silicon substrate; forming a trench, having a lower region and a surface, in the silicon substrate; and forming a doped layer in the silicon substrate in the lower region of the trench. In addition, a roughened silicon layer that has silicon grains with a diameter ranging from essentially 10 to 100 nm is produced in the lower region of the trench. A dielectric intermediate layer is applied on the roughened silicon layer, and the trench is filled with a doped layer.

Abstract: The integrated circuit configuration has at least one buried circuit element and an insulating layer. A multiplicity of insulating regions are in contact with one another to forming a locally delimited insulating layer in the substrate. In this way, trench capacitors implemented as buried circuit elements can be manufactured with a structure size of less than 100 nm in a simple and cost-effective manner.