Abstract: An open form is produced with a plurality of in each case two-dimensionally structured layers. The form is made of silicon which is etchable in dependence on its doping. A first silicon layer is first produced, and a portion of the first layer which belongs to the form to be produced, is marked by doping at least one zone of the first layer. Subsequently, at least one further silicon layer is applied, and a portion belonging to the form is also marked therein. Finally, every unmarked portion of the layers is removed by etching depending on the respective doping of each layer. The open form is, in particular, a photonic crystal.

Abstract: A storage capacitor for a DRAM has a dielectric composed of silicon nitride and has at least two electrodes disposed opposite one another across the dielectric. A material having a high tunneling barrier between the Fermi level of the material and the conduction band of the dielectric is used for the electrodes. Suitable materials for the electrodes are metals such as platinum, tungsten and iridium or silicides.

Abstract: A number of memory cell lines insulated from one another and that respectively comprise a first doped region and a second doped region between which a gate dielectric, which contains a material with charge carrier traps and a number of gate electrodes. The spacing of neighboring gate electrodes is smaller than the dimensions of the gate electrodes. The information is stored by introduction of charge carriers into the gate dielectric. The gate electrodes are preferably manufactured with the assistance of a spacer technique.

Abstract: A first source-drain region, a channel region, and a second source-drain region are arranged one after another in a semiconductor substrate. At least the surface of the channel region and parts of the first source-drain region are covered by a dielectric layer. A ferroelectric layer is disposed on the surface of the dielectric layer between two polarization electrodes. A gate electrode is arranged on the surface of the dielectric layer. The thickness of the dielectric layer is dimensioned such that a remanent polarization of the ferroelectric layer, which is aligned between the two polarization electrodes, produces compensation charges in part of the channel region. The ferroelectric transistor is suitable as a memory cell for a memory cell configuration.

Abstract: An integrated circuit configuration, in particular is a DRAM cell configuration, includes a capacitor disposed on a first substrate and a portion with a contact disposed on a second substrate. The first substrate is connected to the second substrate, with the contact adjoining the capacitor. The first substrate and the second substrate can be connected essentially in an unadjusted manner, if capacitor elements are distributed over the first substrate and a contact surface of the contact is so large that when the substrates are connected, the contact in each case adjoins at least one of the capacitor elements, which then defines the capacitor. The capacitor may include a plurality of capacitor elements, which makes its capacitance especially high. A method is also provided for producing the integrated circuit configuration.

Abstract: A capacitor for a semiconductor configuration and a method for producing a dielectric layer for the capacitor. The dielectric layer consists of cerium oxide, zirconium oxide, hafnium oxide or various films of the materials.

Abstract: A MOS transistor of a memory cell and a bit line connected thereto are disposed on a first surface of a substrate. A capacitor of the memory cell is disposed on a second surface of the substrate, the second surface being opposite to the first surface. A contact is disposed in the substrate and connects the capacitor to the MOS transistor.

Abstract: A method for fabricating a memory cell configuration, which includes the steps of etching isolation trenches into a semiconductor substrate and thereby forming webs between the isolation trenches and producing bit lines after channel regions have been produced. It furthermore includes performing an etching step which results in the isolation trenches penetrating more deeply into the semiconductor substrate.

Abstract: The invention relates to a memory cell configuration in which a plurality of memory cells are present in the region of a main area of a semiconductor substrate (10), and in which the memory cells each contain at least one MOS transistor having a source (29), gate (WL1 and WL2) and drain (60). The memory cells are configured in memory cell rows which run essentially parallel, in which adjacent memory cell rows are insulated by an isolation trench (20), in which adjacent memory cell rows each contain at least one bit line (60), and where the bit lines (60) of two adjacent memory cell rows face one another. The memory cell configuration is constructed in such a way that the isolation trench (20) penetrates more deeply into the semiconductor substrate (10) than the bit lines (60), and at least one of the source (29) and/or of the drain is at least partially situated underneath the isolation trench (20). The invention furthermore relates to a method for fabricating this memory cell configuration.

Abstract: A ferroelectric transistor suitable as a memory element has a first gate intermediate layer and a first gate electrode disposed on the surface of a semiconductor substrate and disposed between source/drain regions. The first gate intermediate layer contains at least one ferroelectric layer. In addition to the first gate intermediate layer, a second gate intermediate layer and a second gate electrode are configured between the source/drain regions. The second gate intermediate layer contains a dielectric layer. The first gate electrode and the second gate electrode are connected to each other via a diode structure.

Abstract: A DRAM capacitor is described that contains a BaSrTiO3 (BST) dielectric. The dielectric has a three-layer structure enabling the formation of a potential trough in which electrons can be permanently trapped.

Abstract: An integrated circuit configuration includes a structure, a p-n junction, and a defect plane disposed such that each of a plurality of straight lines, that intersect or touch the structure and the p-n junction, intersect the defect plane. This prevents unwanted leakage currents through the p-n junction and increases a retention time in a DRAM cell configuration. A wafer configuration and a method of producing an integrated circuit configuration are also provided.

Abstract: A memory cell configuration in a semiconductor substrate is proposed, in which the semiconductor substrate is of the first conductivity type. Trenches which run parallel to one another are incorporated in the semiconductor substrate, and first address lines run along the side walls of the trenches. Second address lines are formed on the semiconductor substrate, transversely with respect to the trenches. Semiconductor substrate regions, in which a diode and a dielectric whose conductivity can be changed are arranged, are located between the first address lines and the second address lines. A suitable current pulse can be used to produce a breakdown in the dielectric, with information thus being stored in the dielectric.

Abstract: A manufacturing method for a capacitor in an integrated memory circuit includes initially depositing a first conducting layer and an auxiliary layer acting as an etch-stop onto a carrier. Then a layer sequence which contains alternating layers of the first material and a second material is produced on top of the first conducting layer and the auxiliary layer. The layer sequence may, in particular, have p+/p− silicon layers or silicon/germanium layers. A layer structure with a base of a capacitor to be produced is formed from the layer sequence. Sides of the layer structure are provided with a conducting supporting structure. An opening is formed inside the layer structure, all the way down to the auxiliary layer and then the auxiliary layer and the layers made of the second material are removed. A free surface of the layers made of the first material and the supporting structure are provided with a capacitor dielectric onto which a counter electrode is applied.

Abstract: A method for the fabrication of a doped silicon layer, includes carrying out deposition by using a process gas containing SiH4, Si2H6 and a doping gas. The doped silicon layer which is thus produced can be used both as a gate electrode of an MOS transistor and as a conductive connection. At a thickness between 50 and 200 nm it has a resistivity less than or equal to 0.5 m&OHgr;cm.

Abstract: An integrated electrical circuit has at least one memory cell, in which the memory cell is disposed in the region of a surface of a semiconductor substrate. The memory cell contains at least two inverters that are electrically connected to one another. The inverters each contain two complementary MOS transistors having a source, a drain and a channel, the channels of the complementary MOS transistors having different conductivity types. According to the invention, the integrated electrical circuit is constructed in such a way that the inverters are disposed perpendicularly to the surface of the semiconductor substrate. The source, the drain and the channel of the complementary MOS transistors are formed by layers which lie one on top of the other and are disposed in such a way that the complementary MOS transistors are situated one above the other. The invention furthermore relates to a method for fabricating the integrated electrical circuit.

Abstract: An electrically programmable memory cell array is formed of memory cells, which include a vertical MOS transistor. The MOS transistor has a gate dielectric of a material with charge carrier traps. The memory cells are disposed along opposite edges of striplike, parallel insulation trenches. The width and spacing of the insulation trenches are preferably identical. The space required per memory cell of the memory cell array is 2F2, where F is the minimum structural size in the technology employed. The memory cells are programmed by selectively injecting electrons into the gate dielectric.

Abstract: In producing a silicon capacitor, hole structures (2) are created in a silicon substrate (1), at the surface of which structures a conductive zone (3) is created by doping and whose surface is provided with a dielectric layer (4) and a conductive layer (5), without filling the hole structures (2). To compensate mechanical strains upon the silicon substrate (1) which are effected by the doping of the conductive zone (3), a conformal auxiliary layer (6) is formed on the surface of the conductive layer (5), which auxiliary layer is under a compressive mechanical stress.

Abstract: For the manufacture of a memory cell arrangement with first memory cells that comprise a vertical MOS transistor and with second memory cells that do not comprise an MOS transistor, whereby the memory cells are arranged along opposite edges of strip-type trenches, memory cells that are adjacent along the trenches (5) are manufactured successively. The spacing of adjacent memory cells is determined in particular by means of a spacer technology. By this means, a space requirement per memory cell of 1F.sup.2 can be realized, whereby F is the minimum structural size of the respective technology.

Abstract: For manufacturing a capacitor that is essentially suited for DRAM arrangements, column structures that form an electrode of the capacitor are etched upon employment of a statistical mask that is produced without lithographic steps by nucleus formation of Si/Ge and subsequent selective epitaxy. Structure sizes below 100 nm can be realized in the statistical mask. Surface enlargement factors up to 60 are thus achieved.