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 multi-level memory array is described employing rail-stacks. The rail-stacks include a conductor and semiconductor layers. The rail-stacks are generally separated by an insulating layer used to form antifuses. In one embodiment, one-half the diode is located in one rail-stack and the other half in the other rail-stack.

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 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 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: Silicon nitride antifuses can be advantageously used in memory arrays employing diode-antifuse cells. Silicon nitride antifuses can be ruptured faster and at a lower breakdown field than antifuses formed of other materials, such as silicon dioxide. Examples are given of monolithic three dimensional memory arrays using silicon nitride antifuses with memory cells disposed in rail-stacks and pillars, and including PN and Schottky diodes. Pairing a silicon nitride antifuse with a low-density, high-resistivity conductor gives even better device performance.

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 multi-level memory array is described employing rail-stacks. The rail-stacks include a conductor and semiconductor layers. The rail-stacks are generally separated by an insulating layer used to form antifuses. In one embodiment, one-half the diode is located in one rail-stack and the other half in the other rail-stack.

Abstract: A memory cell for a 3-D integrated circuit memory is described. An antifuse region is sandwiched between two heavily doped regions of the same conductivity type.

Abstract: A three-dimensional memory array includes a plurality of rail-stacks on each of several levels forming alternating levels of X-lines and Y-lines for the array. Memory cells are formed at the intersection of each X-line and Y-line. The memory cells of each memory plane are all oriented in the same direction relative to the substrate, forming a serial chain diode stack. In certain embodiments, row and column circuits for the array are arranged to interchange function depending upon the directionality of memory cells in the selected memory plane. High-voltage drivers for the X-lines and Y-lines are each capable of passing a write current in either direction depending on the direction of the selected memory cell. A preferred bias arrangement reverse biases only unselected memory cells within the selected memory plane, totaling approximately N2 memory cells, rather than approximately 3N2 memory cells as with prior arrays.

Abstract: The invention is directed to a method of forming a three dimensional circuit including introducing a three dimensional circuit over a substrate. In one embodiment, the three dimensional circuit includes a circuit structure in a stacked configuration between a first signal line and a second signal line, where the two signal lines comprise similar materials. The method includes selectively patterning the second signal line material and the circuit without patterning the first signal line. One way the second signal line is patterned without patterning the first signal line is by modifying the etch chemistry. A second way the second signal line is patterned without patterning the first signal line is by including an etch stop between the first signal line and the second signal line. The invention is also directed at targeting a desired edge angle of a stacked circuit structure.

Abstract: Postponing at least some thermal processing operations, as multiple levels of a three dimensional circuit are formed.

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: A three-dimensional memory array includes a plurality of rail-stacks on each of several levels forming alternating levels of X-lines and Y-lines for the array. Memory cells are formed at the intersection of each X-line and Y-line. The memory cells of each memory plane are all oriented in the same direction relative to the substrate, forming a serial chain diode stack. In certain embodiments, row and column circuits for the array are arranged to interchange function depending upon the directionality of memory cells in the selected memory plane. High-voltage drivers for the X-lines and Y-lines are each capable of passing a write current in either direction depending on the direction of the selected memory cell. A preferred bias arrangement reverse biases only unselected memory cells within the selected memory plane, totaling approximately N2 memory cells, rather than approximately 3N2 memory cells as with prior arrays.

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: 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: 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: 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.

Abstract: A low-cost memory cell array includes multiple, vertically-stacked layers of memory cells. In one form, each memory cell is characterized by a small cross-sectional area and a read current less than 6.3 microamperes. The resulting memory array has a slow access time and is well-suited for digital media storage, where access time requirements are low and the dramatic cost reductions associated with the disclosed memory arrays are particularly attractive. In another form, each memory cell includes an antifuse layer and diode components, wherein at least one diode component is heavily doped (to a dopant concentration greater than 1019/cm3), and wherein the read current is large (up to 500 mA).

Abstract: A three-dimensional memory array includes a plurality of rail-stacks on each of several levels forming alternating levels of X-lines and Y-lines for the array. Memory cells are formed at the intersection of each X-line and Y-line. The memory cells of each memory plane are all oriented in the same direction relative to the substrate, forming a serial chain diode stack. In certain embodiments, row and column circuits for the array are arranged to interchange function depending upon the directionality of memory cells in the selected memory plane. High-voltage drivers for the X-lines and Y-lines are each capable of passing a write current in either direction depending on the direction of the selected memory cell. A preferred bias arrangement reverse biases only unselected memory cells within the selected memory plane, totaling approximately N2 memory cells, rather than approximately 3N2 memory cells as with prior arrays.