Although photolithography is the preferred pattern-transfer method for even the 10 nm electrically-programmable memory (EPM, which comprises only periodic patterns), imprint-lithography is the preferred method to form the sub-25 nm printed memory (which comprises at least one non-periodic data-pattern). Accordingly, the present invention discloses an imprinted memory.

The present invention discloses a three-dimensional 3D-oP (three-dimensional offset-printed memory)-based package (3D.sup.2-oP). The mask-patterns for different dice in a same 3D.sup.2-oP package are merged onto a same data-mask. At different printing steps, a wafer is offset by different values with respect to the data-mask. Accordingly, data-patterns from a same data-mask are printed into different dice in a same 3D.sup.2-oP package.

The present invention discloses an offset-printing method for a three-dimensional printed memory with multiple bits-per-cell. The mask-patterns for different bits-in-a-cell are merged onto a multi-region data-mask. At different printing steps, a wafer is offset by different values with respect to the data-mask. Accordingly, data-patterns from a same data-mask are printed into different bits-in-a-cell.

The present invention discloses an offset-printing method for a three-dimensional 3D-oP (three-dimensional offset-printed memory)-based package. The mask-patterns for different 3D-op dice are merged onto a same data-mask. At different printing steps, a wafer is offset by different values with respect to the data-mask. Accordingly, data-patterns from a same data-mask are printed into different 3D-oP dice.

The present invention discloses a three-dimensional offset-printed memory (3D-oP) with multiple bits-per-cell. The mask-patterns for different bits-in-a-cell are merged onto a same data-mask. At different printing steps, a wafer is offset by different values with respect to the data-mask. Accordingly, data-patterns from a same data-mask are printed into different bits-in-a-cell.

The present invention discloses an offset-printing method for a three-dimensional printed memory. The mask-patterns for different memory levels are merged onto a multi-region data-mask. At different printing steps, a wafer is offset by different values with respect to the data-mask. Accordingly, data-patterns from a same data-mask are printed into different memory levels.

A die stack comprises a first integrated circuit (IC) die having at least a first device comprising a first source, a first drain and a first gate electrode above a first channel region between the first source and the first drain. A second IC die has at least a second device comprising a second source, a second drain and a second gate electrode above a second channel region between the second source and the second drain. The second gate electrode is connected to the first gate electrode by a path including a first through substrate via (TSV), the second drain connected to the first source by a path including a second TSV.

Methods, systems, and devices for split pillar architectures for memory devices are described. A memory device may include a substrate arranged with conductive contacts in a pattern and openings through alternative layers of conductive and insulative material that may decrease the spacing between the openings while maintaining a dielectric thickness to sustain the voltage to be applied to the array. After etching material, an insulative material may be deposited in a trench. Portions of the insulative material may be removed to form openings, into which cell material is deposited. Conductive pillars may extend perpendicular to the planes of the conductive material and the substrate, and couple to conductive contacts. The conductive pillars may be divided to form first and second pillars.

A three-dimensional integrated circuit includes a first transistor, a word line, a first via, a second transistor, and a second via. The first transistor is on a first level and the second transistor is on a second level. The second level is different from the first level. The word line and the first via are coupled to the first transistor. The second via is coupled between the first transistor and the second transistor.

A ROM cell includes first and second three-dimensional transistors. The second transistor is formed above the first transistor, and the channel portions of the first and second transistors overlap each other. First data is stored depending on whether first and second local interconnects connected to the nodes of the first transistor are connected to a same line, or different lines, out of a bit line and a ground power supply line. Second data is stored depending on whether third and fourth local interconnects connected to the nodes of the second transistor are connected to a same line, or different lines, out of a bit line and a ground power supply line.