Abstract: A method of manufacturing semiconductor structures is disclosed. In one embodiment, a first mask is provided above a substrate. The first mask includes first mask lines extending along a first axis. A second mask is provided above the first mask. The second mask includes second mask lines extending along a second axis that intersects the first axis. At least one of the first and second masks is formed by a pitch fragmentation method. Structures may be formed in the substrate, wherein the first and the second mask are effective as a combined mask. The structures may be equally spaced at a pitch in the range of a minimum lithographic feature size for repetitive line structures.

Abstract: A hard mask layer stack for patterning a layer to be patterned includes a carbon layer disposed on top of the layer to be patterned, a first layer of a material selected from the group of SiO2 and SiON disposed on top of the carbon layer and a silicon layer disposed on top of the first layer. A method of patterning a layer to be patterned includes providing the above described hard mask layer stack on the layer to be patterned and patterning the silicon hard mask layer in accordance with a pattern to be formed in the layer that has to be patterned.

Abstract: The bit lines are produced by an implantation of a dopant by means of a sacrificial hard mask layer, which is later replaced with the gate electrodes formed of polysilicon in the memory cell array. Striplike areas of the memory cell array, which run transversely to the bit lines, are reserved by a blocking layer to be occupied by the bit line contacts. In these areas, the hard mask is used to form contact holes, which are self-aligned with the implanted buried bit lines. Between the blocked areas, the word lines are arranged normally to the bit lines.

Abstract: A carrier is structured with isolation regions in a precise fashion. First structures and second structures are formed above a carrier. At least one of the second structures is removed selectively with respect to the first structures. At least one recess in the carrier is formed according to the structure thus obtained. An embodiment of a semiconductor device that may be produced in this way is provided with at least one insulating striplike region and/or a plurality of insulating regions that are arranged at distances from one another along a line.

Abstract: A method of manufacturing semiconductor structures is disclosed. In one embodiment, a first mask is provided above a substrate. The first mask includes first mask lines extending along a first axis. A second mask is provided above the first mask. The second mask includes second mask lines extending along a second axis that intersects the first axis. At least one of the first and second masks is formed by a pitch fragmentation method. Structures may be formed in the substrate, wherein the first and the second mask are effective as a combined mask. The structures may be equally spaced at a pitch in the range of a minimum lithographic feature size for repetitive line structures.

Abstract: A memory device includes a semiconductor substrate having a surface, a plurality of first and second conductive lines, a plurality of memory cells, and a plurality of landing pads. Each of the first conductive lines has a line width wb and two neighboring ones of the first conductive lines having a distance bs from each other. Each of the second conductive lines has a line width wl and two neighboring ones of the second conductive lines having a distance ws from each other. Each memory cell is accessible by addressing corresponding ones of said first and second conductive lines. Each of the landing pads are made of a conductive material and are connected with a corresponding one of said second conductive lines.

Abstract: Spacers are formed on sidewalls of striplike parts of a pattern layer of periodic structure. The pattern layer is removed, and the spacers are covered with a further spacer layer, which is then structured to second sidewall spacers. Gaps between the spacers are filled with a complementary layer. The upper surface is planarized to a lower surface level, leaving a periodic succession of the first spacers, the second spacers and the residual parts of the complementary layer. The lateral dimensions are adapted in such a manner that a removal of one or two of the remaining layers renders a periodic pattern of smaller pitch.

Abstract: A hard mask layer stack for patterning a layer to be patterned includes a carbon layer disposed on top of the layer to be patterned, a first layer of a material selected from the group of SiO2 and SiON disposed on top of the carbon layer and a silicon layer disposed on top of the first layer. A method of patterning a layer to be patterned includes providing the above described hard mask layer stack on the layer to be patterned and patterning the silicon hard mask layer in accordance with a pattern to be formed in the layer that has to be patterned.

Abstract: At least one memory layer is provided on a substrate surface. A plurality of parallel conductor strips is formed from electrically conductive material above the memory layer. Sidewalls of the conductor strips are provided with spacers of an electrically conductive material.

Abstract: A hard mask layer stack for patterning a layer to be patterned includes a carbon layer disposed on top of the layer to be patterned, a first layer of a material selected from the group of SiO2 and SiON disposed on top of the carbon layer and a silicon layer disposed on top of the first layer. A method of patterning a layer to be patterned includes providing the above described hard mask layer stack on the layer to be patterned and patterning the silicon hard mask layer in accordance with a pattern to be formed in the layer that has to be patterned.

Abstract: A first hardmask layer is provided over a substrate, and a second hardmask layer is provided over the first hardmask layer. The second hardmask layer is patterned to form a second hardmask structure having sidewalls. A sacrificial layer of a sacrificial material is conformally deposited such that the deposited sacrificial layer has substantially horizontal and vertical portions. The horizontal portions of the sacrificial layer are removed to form lines of the sacrificial material adjacent to the sidewalls of the second hardmask lines. The sacrificial layer is at least partially removed to structure the sacrificial material and the remaining sacrificial layer is used to structure the first hardmask. The second hardmask structures is removed to uncover portions of the first hardmask. Uncovered portions of the substrate are etched, thereby forming structures in the substrate below the first hardmask.

Abstract: An array of conductive lines is formed on or at least partially in a semiconductor substrate. The array includes a number of conductive lines extending in a first direction, a number of landing pads made of a conductive material, with individual landing pads being connected to corresponding ones of the conductive lines, wherein the conductive lines include first and second subsets of conductive lines. The conductive lines of the first subset alternate with the conductive lines of the second subset, wherein the landing pads connected to the conductive lines of the first subset are disposed on a first side of the conductive lines, and the landing pads connected to the conductive lines of the second subset are disposed on a second side of the conductive lines, the first side being opposite to the second side.

Abstract: Final sections of the word lines are arranged in a staggered fashion to fan out and have larger lateral extensions than the word lines. Interspaces are filled with a dielectric material, and a mask is applied that partially covers the final sections and leaves contact areas in regions adjacent to the final sections and to the interspaces open. This mask is used to remove the dielectric material between the word line stacks. A second word line layer is applied and planarized to form second word lines between the first word lines, which have contact areas arranged in a staggered fashion to fan out like the final sections of the first word lines.

Abstract: A memory device includes a semiconductor substrate having a surface, a plurality of first and second conductive lines, a plurality of memory cells, and a plurality of landing pads. Each of the first conductive lines has a line width wb and two neighboring ones of the first conductive lines having a distance bs from each other. Each of the second conductive lines has a line width wl and two neighboring ones of the second conductive lines having a distance ws from each other. Each memory cell is accessible by addressing corresponding ones of said first and second conductive lines. Each of the landing pads are made of a conductive material and are connected with a corresponding one of said second conductive lines.

Abstract: Final sections of the word lines are arranged in a staggered fashion to fan out and have larger lateral extensions than the word lines. Interspaces are filled with a dielectric material, and a mask is applied that partially covers the final sections and leaves contact areas in regions adjacent to the final sections and to the interspaces open. This mask is used to remove the dielectric material between the word line stacks. A second word line layer is applied and planarized to form second word lines between the first word lines, which have contact areas arranged in a staggered fashion to fan out like the final sections of the first word lines.

Abstract: The bit lines are produced by an implantation of a dopant by means of a sacrificial hard mask layer, which is later replaced with the gate electrodes formed of polysilicon in the memory cell array. Striplike areas of the memory cell array, which run transversely to the bit lines, are reserved by a blocking layer to be occupied by the bit line contacts. In these areas, the hard mask is used to form contact holes, which are self-aligned with the implanted buried bit lines. Between the blocked areas, the word lines are arranged normally to the bit lines.

Abstract: Spacers are formed on sidewalls of striplike parts of a pattern layer of periodic structure. The pattern layer is removed, and the spacers are covered with a further spacer layer, which is then structured to second sidewall spacers. Gaps between the spacers are filled with a complementary layer. The upper surface is planarized to a lower surface level, leaving a periodic succession of the first spacers, the second spacers and the residual parts of the complementary layer. The lateral dimensions are adapted in such a manner that a removal of one or two of the remaining layers renders a periodic pattern of smaller pitch.

Abstract: A method and a device for sorting wafers from an initial state into an end state. The wafers are at least partly identifiable as elements of a finite sequence based on an information carrier. In the initial state, the wafers are arranged in any desired sequence in compartments of a holding device and in the end state each wafer is arranged in accordance with its position in the sequence in the compartments of the holding device. The first wafer is removed from a first compartment of the holding device. The information carrier of the first wafer is read by a reading device to determine the position of the first wafer in the sequence. Subsequently, a second wafer is removed from a second compartment corresponding to the position of the first wafer in the sequence. The first wafer is moved into the compartment corresponding to its position in the sequence.

Abstract: The invention relates to a method for sorting wafers (W) of a chip production operation from an initial state into an end state, the wafers (W) being at least partly identifiable on the basis of an information carrier as elements of a finite sequence, and in the initial state the wafers (W) being arranged in any desired sequence in compartments (s) of a holding device (H) and in the end state each wafer (W) being arranged as far as possible in accordance with its position in the sequence in the compartments (s) of the holding device (H), characterized in that