Abstract: A 3D semiconductor memory is described having rail-stacks which define conductive lines and cells. The memory levels are organized in pairs with each pair showing common lines in adjacent levels.

Abstract: A three dimensional circuit structure including tapered pillars between first and second signal lines. An apparatus including a first plurality of spaced apart coplanar conductors disposed in a first plane over a substrate; a second plurality of spaced apart coplanar conductors disposed in a second plane, the second plane parallel to and different from the first plane; and a plurality of cells disposed between one of the first conductors and one of the second conductors, wherein each of the plurality of cells have a re-entrant profile.

Abstract: The present invention is a level of an integrated circuit. The level of integrated circuit has a first area having a plurality of features having a first density and the level of the integrated circuit has a second area adjacent to the first area wherein the second area has a plurality of dummy features having a density substantially similar to the first density.

Abstract: The preferred embodiments described herein relate to an integrated circuit and method for selecting a set of memory-cell-layer-dependent or temperature-dependent operating conditions. In one preferred embodiment, a memory array is provided comprising a plurality of memory cells arranged in L layers stacked vertically above one another in a single integrated circuit. A memory cell layer in the memory array is selected, and one of N sets of memory-cell-layer-dependent writing conditions and/or one of K sets of memory-cell-layer-dependent reading conditions is selected based on the selected memory cell layer. In another preferred embodiment, a temperature of an integrated circuit is measured, and a set of writing conditions and/or a set of reading conditions is selected based on the measured temperature. Other preferred embodiments are provided, and each of the preferred embodiments can be used alone or in combination with one another.

Abstract: A method of forming an active device is provided. The method includes performing a first patterning operation on a first plurality of layers. This first patterning operation defines a first feature of the active device. Then, a second patterning operation can be performed on at least one layer of the first plurality of layers. This second patterning operation defines a second feature of the active device. Of importance, the first and second patterning operations are performed substantially back-to-back, thereby ensuring that the active device can accurately function.

Abstract: There is provided a monolithic three dimensional array of charge storage devices which includes a plurality of device levels, wherein at least one surface between two successive device levels is planarized by chemical mechanical polishing.

Abstract: A 3D semiconductor memory is described having rail-stacks which define conductive lines and cells. The memory levels are organized in pairs with each pair showing common lines in adjacent levels.

Abstract: A method to form a vertical interconnect advantageous for high-density semiconductor devices. A conductive etch stop layer, preferably of cobalt silicide, is formed. The etch stop layer may be in the form of patterned lines or wires. A layer of contact material is formed on and in contact with the etch stop layer. The layer of contact material is patterned to form posts. Dielectric is deposited over and between the posts, then the dielectric planarized to expose the tops of the posts. The posts can serve as vertical interconnects which electrically connect a next conductive layer formed on and in contact with the vertical interconnects with the underlying etch stop layer. The patterned dimension of vertical interconnects formed according to the present invention can be substantially the same as the minimum feature size, even at very small minimum feature size.

Abstract: There is provided a monolithic three dimensional array of charge storage devices which includes a plurality of device levels, wherein at least one surface between two successive device levels is planarized by chemical mechanical polishing.

Abstract: The present invention is a level of an integrated circuit. The level of integrated circuit has a first area having a plurality of features having a first density and the level of the integrated circuit has a second area adjacent to the first area wherein the second area has a plurality of dummy features having a density substantially similar to the first density.

Abstract: A three-dimensional, field-programmable, non-volatile memory includes multiple layers of first and second crossing conductors. Pillars are self-aligned at the intersection of adjacent first and second crossing conductors, and each pillar includes at least an anti-fuse layer. The pillars form memory cells with the adjacent conductors, and each memory cell includes first and second diode components separated by the anti-fuse layer. The diode components form a diode only after the anti-fuse layer is disrupted.

Abstract: An apparatus including a circuit of n circuit levels formed over a substrate from a first level to a nth level, wherein n is greater than one, and each of the n circuit levels has a material parameter change that is at least in part caused by a thermal processing operation that is applied to more than one of the n circuit levels simultaneously. An apparatus including a circuit of a plurality of circuit levels, each of the plurality of circuit levels having substantially similar material parameters.

Abstract: The present invention is directed to novel antifuse arrays and their methods of fabrication. According to an embodiment of the present invention an array comprises a plurality of first spaced apart rail-stacks having a top semiconductor material. A fill dielectric is located between the first plurality of spaced apart rail-stacks wherein the fill dielectric extends above the top surface of the semiconductor material. An antifuse material is formed on the top of the semiconductor material of the first plurality of spaced apart rail-stacks. A second plurality of spaced apart rail-stacks having a lower semiconductor material is formed on the antifuse material. In the second embodiment of the present invention the array comprises a first plurality of spaced apart rail-stacks having a top semiconductor material. A fill dielectric is located between the first plurality of spaced apart rail-stacks wherein the fill dielectric is recessed below the top surface of the semiconductor material.

Abstract: The preferred embodiments described herein relate to an integrated circuit and method for selecting a set of memory-cell-layer-dependent or temperature-dependent operating conditions. In one preferred embodiment, a memory array is provided comprising a plurality of memory cells arranged in L layers stacked vertically above one another in a single integrated circuit. A memory cell layer in the memory array is selected, and one of N sets of memory-cell-layer-dependent writing conditions and/or one of K sets of memory-cell-layer-dependent reading conditions is selected based on the selected memory cell layer. In another preferred embodiment, a temperature of an integrated circuit is measured, and a set of writing conditions and/or a set of reading conditions is selected based on the measured temperature. Other preferred embodiments are provided, and each of the preferred embodiments can be used alone or in combination with one another.

Abstract: A method of forming an active device is provided. The method includes performing a first patterning operation on a first plurality of layers. This first patterning operation defines a first feature of the active device. Then, a second patterning operation can be performed on at least one layer of the first plurality of layers. This second patterning operation defines a second feature of the active device. Of importance, the first and second patterning operations are performed substantially back-to-back, thereby ensuring that the active device can accurately function.

Abstract: The present invention is a level of an integrated circuit. The level of integrated circuit has a first area having a plurality of features having a first density and the level of the integrated circuit has a second area adjacent to the first area wherein the second area has a plurality of dummy features having a density substantially similar to the first density.

Abstract: A method of forming an active device is provided. The method includes performing a first patterning operation on a first plurality of layers. This first patterning operation defines a first feature of the active device. Then, a second patterning operation can be performed on at least one layer of the first plurality of layers. This second patterning operation defines a second feature of the active device. Of importance, the first and second patterning operations are performed substantially back-to-back, thereby ensuring that the active device can accurately function.

Abstract: A 3D semiconductor memory is described having rail-stacks which define conductive lines and cells. The memory levels are organized in pairs with each pair showing common lines in adjacent levels.

Abstract: A memory cell for a two- or a three-dimensional memory array includes first and second conductors and set of layers situated between the conductors. This set of layers includes a dielectric rupture anti-fuse layer having a thickness less than 35 Å and a leakage current density (in the unruptured state) greater than 1 mA/cm2 at 2 V. This low thickness and high current leakage density provide a memory cell with an asymmetric dielectric layer breakdown voltage characteristic. The antifuse layer is formed of an antifuse material characterized by a thickness Tminlife at which the antifuse material is ruptured by a minimum number of write pulses having a polarity that reverse biases diode components included in the memory cell. The average thickness T of the antifuse layer is less than the thickness Tminlife.

Abstract: A method of making a silicon-based electronic device is provided. The method includes, for example, the steps of forming a doped silicon layer on a surface of a substrate material and forming an undoped silicon capping layer on the doped silicon layer. The thin “capping” layers of undoped silicon prevent outgassing of the dopants underneath the cap. In this manner, the next deposition of doped silicon is not subject to autodoping by the previous doped silicon deposition.