Abstract: The present invention is a multibit nonvolatile memory and its method of fabrication. According to the present invention a silicon channel body having a first and second channel surface is formed. A charge storage medium is formed adjacent to the first channel surface and a second charge storage medium is formed adjacent to the second channel surface. A first control gate is formed adjacent to the first charge storage medium adjacent to the first channel surface and a second control gate is formed adjacent to the second charge storage medium adjacent to the second surface.

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 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 contact/via comprising and its method of fabrication. The contact/via of the present invention includes a conductive film. An opening having a top and bottom is formed on the conductive film. The opening has a first sidewall and a second sidewall wherein the first sidewall is opposite the second sidewall. The first sidewall has a stair step configuration such that the first sidewall is closer to the second sidewall at the bottom of the opening than at the top of the opening. A conductive film is then formed on the first sidewall in the opening and on the bottom of the opening on the conductive film.

Abstract: Wafers of the present invention comprise a semiconductor layer and a dielectric layer. The semiconductor layer is patterned to form semiconductor regions, and the dielectric layer is deposited on top of the semiconductor layer. Chemical mechanical planarization (CMP) is performed to remove a portion of the dielectric layer, exposing the upper surfaces of the semiconductor regions. The amount of CMP necessary to expose all of the semiconductor regions on the wafer is reduced, because the dielectric is targeted to deposit up to the upper edge of the semiconductor regions in the spaces in between the semiconductor regions. This technique reduces non-uniformities in the thickness of the dielectric and semiconductor layers across the wafer. The thickness of the dielectric or semiconductor layer deposited on polish monitor pads located at the edges of each die may be monitored to determine when enough CMP has been performed to expose each of the semiconductor regions.

Abstract: A very high density field programmable memory is disclosed. An array is formed vertically above a substrate using several layers, each layer of which includes vertically fabricated memory cells. The cell in an N level array may be formed with N+1 masking steps plus masking steps needed for contacts. Maximum use of self alignment techniques minimizes photolithographic limitations. In one embodiment the peripheral circuits are formed in a silicon substrate and an N level array is fabricated above the substrate.

Abstract: A field emission display (FED) having a correction system with a correction coefficient derived from emission current is presented. Within one embodiment in accordance with the present invention, a field emission display has an anode at the faceplate and a focus structure. The anode potential is held at ground while the focus structure potential is held between, but is not limited to, 40 and 50 volts. The current flowing to the focus structure is measured and used as the basis for the correction coefficient for the field emission display.

Abstract: Dummy wafers that are used in IC manufacturing and methods for manufacturing the same are described. The dummy wafers are made with an increased resistance to breaking during CVD manufacturing process. The dummy wafers are made by placing a protective film over the wafer surface(s) exposed during the CVD process. By increasing the resistance to breaking, the protective film extends the useful life of the dummy wafers.

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.

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 a multibit nonvolatile memory and its method of fabrication. According to the present invention a silicon channel body having a first and second channel surface is formed. A charge storage medium is formed adjacent to the first channel surface and a second charge storage medium is formed adjacent to the second channel surface. A first control gate is formed adjacent to the first charge storage medium adjacent to the first channel surface and a second control gate is formed adjacent to the second charge storage medium adjacent to the second surface.

Abstract: A three-dimensional memory array and method for storing data bits and ECC bits therein is provided. A three-dimensional memory array of the type that includes multiple vertically-stacked layers of memory cells is described. The three-dimensional memory array comprises a plurality of memory cells arranged in a plurality of physically-independent sub-arrays, and data bits and error checking and correcting (ECC) bits of a word are stored in respective ones of the physically-independent sub-arrays. By spatially diffusing data bits and ECC bits from a word, the likelihood of multiple-bit errors within the word is reduced. This is advantageous since most ECC circuitry is capable of correcting only single-bit errors within a given word.

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: The present invention is a multibit nonvolatile memory and its method of fabrication. According to the present invention a silicon channel body having a first and second channel surface is formed. A charge storage medium is formed adjacent to the first channel surface and a second charge storage medium is formed adjacent to the second channel surface. A first control gate is formed adjacent to the first charge storage medium adjacent to the first channel surface and a second control gate is formed adjacent to the second charge storage medium adjacent to the second surface.

Abstract: Wafer surfaces of the present invention comprise semiconductor and dielectric regions formed in such a way that allows the wafer surface to wet so that residual particles can be removed therefrom during a wet clean. The wafer surface comprises exposed regions of dielectric and semiconductor after a CMP removal process. The percentage of the total wafer surface area that is semiconductor after CMP is less than or equal to than a predetermined fraction, and the remainder of the wafer surface area comprises dielectric. Also, the regions of semiconductor on the wafer surface have a maximum shortest dimension. The combined percentage of semiconductor in the total wafer surface area and the maximum shortest dimensions of each semiconductor region are small enough so that the wafer surface is hydrophilic enough to wet.

Abstract: The preferred embodiments described herein provide a memory device and method for sensing while programming a non-volatile memory cell. In one preferred embodiment, a memory device is provided with a memory cell and a detection circuit. While the memory cell is being programmed, the detection circuit determines whether the memory cell is in a programmed state. If the memory cell is in a programmed state, the programming of the memory cell is terminated. As compared with prior programming approaches, this preferred embodiment reduces programming time and power while increasing programming bandwidth (the number of memory cells that can be programmed per unit time). In another preferred embodiment, a plurality of memory cells along a wordline are programmed simultaneously. Other preferred embodiments are provided, and each of the preferred embodiments can be used alone or in combination with one another.

Abstract: Dummy wafers that are used in IC manufacturing and methods for manufacturing the same are described. The dummy wafers are made with an increased resistance to breaking during CVD manufacturing process. The dummy wafers are made by placing a protective film over the wafer surface(s) exposed during the CVD process. By increasing the resistance to breaking, the protective film extends the useful life of the dummy wafers.

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 present invention is a contact/via comprising and its method of fabrication. The contact/via of the present invention includes a conductive film. An opening having a top and bottom is formed on the conductive film. The opening has a first sidewall and a second sidewall wherein the first sidewall is opposite the second sidewall. The first sidewall has a stair step configuration such that the first sidewall is closer to the second sidewall at the bottom of the opening than at the top of the opening. A conductive film is then formed on the first sidewall in the opening and on the bottom of the opening on the conductive film.