Abstract: The memory cell has transistors that are arranged three-dimensionally. Vertical MOS transistors are arranged on the sidewalls of semiconductor webs, and a plurality of transistors are arranged one above the other on each sidewall. The transistors that are arranged one above the other on a sidewall are connected in series.

Abstract: Significant amounts of pattern distortion were found to be the result of reflowing borophosphosilicate glass (BPSG) and silicon dioxide shrinkage during high temperature junction anneals. In order to remedy this problem, a method for suppressing the pattern distortion by subjecting the wafer coated with BPSG and with silicon dioxide layers to a high temperature anneal before patterning is disclosed. The high temperature anneal densifies the undoped silicon dioxide before patterning, so that shrinkage of the undoped silicon dioxide does not affect the patterning steps.

Abstract: A trench capacitor with an epi layer in the lower portion of the trench. The epi layer serves as the buried plate of the trench capacitor. A diffusion region surrounds the lower portion of the trench to enhance the dopant concentration of the epi layer. The diffusion region is formed by, for example, gas phase doping, plasma doping, or plasma immersion ion implantation.

Abstract: For manufacturing fine structures, nuclei that define the dimensions of the fine structures are formed on the surface of a substrate in a CVD process upon employment of a first process gas that contains SiH.sub.4 and GeH.sub.4 in a carrier gas. The nuclei can be employed both as a mask, for example, when etching or implanting, as will as active or passive component parts that remain in the structure, for example, as charge storages in the dielectric of an EEPROM.

Abstract: In a method for making an electrical connection between a trench storage capacitor and an access transistor in a DRAM cell, the electrical connection is formed through the selectively controlled outdiffusion of either N-type or P-type dopants present in the trench through a single crystalline semiconducting material which is grown by epitaxy (epi) from the trench sidewall. This epitaxially grown single crystalline layer acts as a barrier to excessive dopant outdiffusion which can occur in the processing of conventional DRAMs.

Abstract: A method for making an electrical connection between a trench storage capacitor and an access transistor in a DRAM cell. The electrical connection is formed through the selectively controlled outdiffusion of either N-type or P-type dopants present in the trench through a single crystalline semiconducting material which is grown by epitaxy (epi) from the trench sidewall. This epitaxially grown single crystalline layer acts as a barrier to excessive dopant outdiffusion which can occur in the processing of conventional DRAMs.

Abstract: Capacitors, in particular stacked capacitors for a dynamic memory cell configuration are manufactured by first forming a sequence of layers, which include layers made of a first conductive material alternating with layers made of a second material. The second material can be selectively etched with respect to the first material. Layered structures are formed from the sequence of layers, with the flanks of the layered structures each having a conductive support structure. The layered structures are formed with openings, such as gaps, in which the surface of the layers is exposed. The layers made of the second material are selectively removed with respect to the layers made of the first material. The exposed surface of the layers made of the first material and of the support structure are provided with a capacitor dielectric, onto which a counter-electrode is placed. The capacitor is made by etching p.sup.- -doped polysilicon that is selective to p.sup.+ -doped polysilicon.

Abstract: An insulating layer is applied onto the surface of a semiconductor layer structure having elevations up to a maximum step height. The thickness of the insulating layer is greater than the maximum step height. The insulating layer is structured to have irregularities with an essentially identical lateral expanse in the region of the edges of the elevations. The irregularities are planarized by chemical mechanical polishing and/or by deposition, flowing and etch-back of a planarization layer.

Abstract: A method for the manufacture of a laterally limited single crystal region that is suitable for use as an active part of a transistor, including the steps of: a) providing a substrate made of a single crystal semiconductor material; b) forming a first layer on a surface of the substrate, said first layer being selectively etchable with respect to the substrate; c) forming a second layer on the first layer, the second layer being selectively etchable with respect to the first layer; d) providing an opening in the first and second layers so as to expose an area on the surface of the substrate; e) selectively etching the first layer with respect to the substrate and the second layer so as to provide an undercut between the second layer and the surface of the substrate; f) forming a single crystal region on the exposed surface of the substrate by selective epitaxy: g) doping the second layer such that parts of the second layer adjoining the single-crystal region acting as a channel region form a source region and

Abstract: Rod-shaped or cylindrical structures in the nm range on a substrate of silicon are manufactured. A first cylinder of silicon is selectively epitaxially deposited in the hole of a mask layer of oxide, and the mask layer is removed. The silicon is then oxidized to form an oxide layer having such a thickness that a thinner, second cylinder of silicon having practically the same height as the first cylinder remains. In a last step, this oxide layer is removed, so that the second cylinder forms a freestanding silicon rod on the surface of the substrate.

Abstract: For producing a laterally limited, single-crystal region on a substrate, for example the collector of a bipolar transistor or the active region of a MOS transistor, a mask layer having an opening is produced on the surface of a substrate. The surface of the substrate is exposed within the opening. The cross-section of the opening parallel to the surface of the substrate at the surface of the substrate projects laterally beyond that cross-section at the surface of the mask layer. The sidewall of the opening proceeds essentially perpendicularly relative to the surface of the substrate in the region of the surface of the mask layer and has a step-shaped profile in cross-section perpendicularly relative to the surface of the substrate. The single-crystal region is formed by selective epitaxy within the opening.

Abstract: A method for the manufacture of a laterally limited single crystal region that is suitable for use as an active part of a transistor, including the steps of: a) providing a substrate made of a single crystal semiconductor material; b) forming a first layer on a surface of the substrate, said first layer being selectively etchable with respect to the substrate; c) forming a second layer on the first layer, the second layer being selectively etchable with respect to the first layer; d) providing an opening in the first and second layers so as to expose an area on the surface of the substrate; e) covering surfaces and sidewalls of the second layer with a third layer f) selectively etching the first layer with respect to the substrate and the second layer and the third layer so as to provide an undercut between the second layer and the surface of the substrate; g) forming a single crystal region on the exposed surface of the substrate by selective epitaxy without nucleation occurring at the surface of the third l

Abstract: For manufacturing a component with porous silicon, two highly doped regions with a lightly doped region arranged between them are formed in a silicon wafer. The dopant concentrations are thereby set such that porous silicon arises in the lightly doped region in a subsequent anodic etching. Light-emitting diodes or light-controlled bipolar transistors can be manufactured in this way.

Abstract: A method for the manufacture of a laterally limited single crystal region that is suitable for use as an active part of a transistor.

Abstract: A self-supporting layer of n-doped monocrystalline silicon is stripped from a substrate wafer of n-doped, monocrystalline silicon by electrochemical etching for manufacturing a solar cell. Holes are formed in the substrate wafer by electrochemical etching, particularly in a fluoride-containing, acidic electrolyte wherein the substrate wafer is connected as an anode. When a depth of the holes that essentially corresponds to the thickness of the self-supporting layer is reached, the process parameters of the etching are modified such that the self-supporting layer is stripped as a consequence of the holes growing together. The solar cell is manufactured from the self-supporting layer, and the method can be applied repeatedly on the same substrate wafer for stripping a plurality of self-supporting layers.

Abstract: For manufacturing an electrically conductive tip composed of a doped semiconductor material, a mask layer is produced on a substrate composed of the semiconductor material. This mask layer contains a material at least at its surface and directly on the substrate whereon the semiconductor material does not grow in a selective epitaxy. An opening wherein the surface of the substrate lies exposed is produced in the mask layer. The electrically conductive tip is produced by a selective epitaxy on the exposed surface of the substrate such that the layer growth in the direction parallel to the surface of the substrate is lower than in the direction perpendicular to the surface of the substrate.

Abstract: A planar pn-junction with high electric strength, which separates a semiconductor region inserted in a semiconductor body from the rest of the semiconductor body, has, in its border region, a plurality of field plates which are separated from a semiconductor zone residing below and extending the semiconductor region by an electrically insulating layer. The field plates contact the semiconductor zone in the area of contact holes. The contact holes respectively have set distances between them and the inner and outer field plate edges, whereby below those field plate parts residing between the contact holes and the inner field plates borders, local doping maxima of the semiconductor zone are provided.

Abstract: A turn-off thyristor whereby an n-base layer not contacted by a gate electrode has at least one thin semiconductor layer inserted into it that is oppositely doped. Its distance from a pn-junction between a p-base and the n-base is selected so small that the maximum field strength of the space charge zone building up at this pn-junction upon turn-off of the thyristor is limited to a non-critical value at which an avalanche breakdown with respect to the charge carriers to be cleared out does not yet occur.

Abstract: A semiconductor region that is inserted into a semiconductor member is provided, the latter being separated from the former by a planar pn junction including a first, more highly doped sub-region and a second, more lightly doped sub-region that is limited by a part of the pn junction that gradually approaches a boundary surface of the semiconductor member. An electrode contacts the semiconductor region and covers a part of the second sub-region and extends toward the lateral limitation of the semiconductor region to such an extent that, given the application of a voltage inhibiting the pn junction the space charge zone forming thereat has its edge lying in the boundary surface just reaching the electrode edge given a reduced breakdown voltage.

Abstract: A method for the manufacture of a pn junction having a high breakdown voltage at the boundary surface of a semiconductor body, utilizing a mask which has a relatively large opening for introducing a dopant therethrough into the semiconductor body, the mask having a marginal edge which extends laterally beyond the edge of the relatively large opening. In the marginal edge, the mask is provided with smaller, auxiliary openings, the openings being sized and spaced such that lesser amounts of dopant pass through the opening as the distance of the auxiliary openings from the edge of the relatively larger opening increases. Upon introducing the dopant into the semiconductor body through the mask, there is generated a doping profile which gradually approaches the boundary surface with increasing distance from the edge of the relatively large opening.