Disclosed are mask layout correction methods and a method for fabricating semiconductor devices. The mask layout correction method comprises performing a first optical proximity correction on an initial pattern layout. The step of performing the first optical proximity correction includes providing a target pattern of the initial pattern layout with control points based on a first model, obtaining a predicted contour of the initial pattern layout by performing a simulation, and obtaining an error between the target pattern and the predicted contour from the control points. The control points include first control points on an edge of the target pattern and second control points in an inside of the target pattern. The step of obtaining the error includes acquiring first error values from the first control points, providing weights to the first error values, and acquiring second error values from the second control points.

A memory device includes at least one bit line, at least one word line, and at least one memory cell comprising a capacitor and a transistor. The transistor has a gate terminal coupled to the word line, a first terminal, and a second terminal. The capacitor has a first end coupled to the first terminal of the transistor, a second end coupled to the bit line, and an insulating material between the first end and the second end. The insulating material is configured to break down under a predetermined break-down voltage or higher applied between the first end and the second end.

A memory device includes at least one bit line, at least one word line, and at least one memory cell comprising a capacitor and a transistor. The transistor has a gate terminal coupled to the word line, a first terminal, and a second terminal. The capacitor has a first end coupled to the first terminal of the transistor, a second end coupled to the bit line, and an insulating material between the first end and the second end. The insulating material is configured to break down under a predetermined break-down voltage or higher applied between the first end and the second end.

Examples of a multiple-mask multiple-exposure lithographic technique and suitable masks are provided herein. In some examples, a photomask includes a die area and a stitching region disposed adjacent to the die area and along a boundary of the photomask. The stitching region includes a mask feature for forming an integrated circuit feature and an alignment mark for in-chip overlay measurement.

Examples of a multiple-mask multiple-exposure lithographic technique and suitable masks are provided herein. In some examples, a photomask includes a die area and a stitching region disposed adjacent to the die area and along a boundary of the photomask. The stitching region includes a mask feature for forming an integrated circuit feature and an alignment mark for in-chip overlay measurement.

A semiconductor device includes: an active area in a transistor layer; contact-source/drain (CSD) conductors in the transistor layer; gate conductors in the transistor layer, and interleaved with the CSD conductors; VG structures in the transistor layer, and over the active area; and a first gate-signal-carrying (GSC) conductor in an M_1st layer that is over the transistor layer, and that is over the active area; and wherein long axes correspondingly of the active area and the first GSC conductor extend substantially in a first direction; and long axes correspondingly of the CSD conductors and the gate conductors extend substantially in a second direction, the second direction being substantially perpendicular to the first direction.

A semiconductor device includes: an active area in a transistor layer; contact-source/drain (CSD) conductors in the transistor layer; gate conductors in the transistor layer, and interleaved with the CSD conductors; VG structures in the transistor layer, and over the active area; and a first gate-signal-carrying (GSC) conductor in an M_1st layer that is over the transistor layer, and that is over the active area; and wherein long axes correspondingly of the active area and the first GSC conductor extend substantially in a first direction; and long axes correspondingly of the CSD conductors and the gate conductors extend substantially in a second direction, the second direction being substantially perpendicular to the first direction.

An overlay correcting method capable of optimizing correction of an overlay within a scanner correction limit of a scanner of a scanner system, and a photolithography method, a semiconductor device manufacturing method and the scanner system which are based on the overlay correcting method are provided. The overlay correcting method includes collecting overlay data by measuring an overlay of a pattern; calculating correction parameters of the overlay by performing regularized regression using the overlay data, the regularized regression being based on a correction limit of the scanner such that the correction parameters fall within the correction limit of the scanner; and providing the correction parameters to the scanner.

An overlay correcting method capable of optimizing correction of an overlay within a scanner correction limit of a scanner of a scanner system, and a photolithography method, a semiconductor device manufacturing method and the scanner system which are based on the overlay correcting method are provided. The overlay correcting method includes collecting overlay data by measuring an overlay of a pattern; calculating correction parameters of the overlay by performing regularized regression using the overlay data, the regularized regression being based on a correction limit of the scanner such that the correction parameters fall within the correction limit of the scanner; and providing the correction parameters to the scanner.

A photoresist film is patterned into an array of island shapes with improved critical dimension uniformity and no phase edges by using two alternating phase shifting masks (AltPSMs) and one post expose bake (PEB). The photoresist layer is exposed with a first AltPSM having a line/space (L/S) pattern where light through alternating clear regions on each side of an opaque line is 180° phase shifted. Thereafter, there is a second exposure with a second AltPSM having a L/S pattern where opaque lines are aligned orthogonal to the lengthwise dimension of opaque lines in the first exposure, and with alternating 0° and 180° clear regions. Then, a PEB and subsequent development process are used to form an array of island shapes. The double exposure method enables smaller island shapes than conventional photolithography and uses relatively simple AltPSM designs that are easier to implement in production than other optical enhancement techniques.