Embodiments of methods and structures for forming a 3D integrated wiring structure are disclosed. The method can include forming an insulating layer on a front side of a first substrate; forming a semiconductor layer on a front side of the insulating layer; patterning the semiconductor layer to expose at least a portion of a surface of the insulating layer; forming a plurality of semiconductor structures over the front side of the first substrate, wherein the semiconductor structures include a plurality of conductive contacts and a first conductive layer; joining a second substrate with the semiconductor structures; performing a thinning process on a backside of the first substrate to expose the insulating layer and one end of the plurality of conductive contacts; and forming a conductive wiring layer on the exposed insulating layer.

An interconnection structure and a method of manufacturing the same, and an electronic device including the interconnection structure are provided. According to an embodiment, the interconnection structure may comprise: a first interconnection line at a first level, comprising at least a first portion extending along a first direction; a second interconnection line at a second level higher than the first level, comprising at least a second portion extending along a second direction crossing the first direction; a via plug disposed between the first portion of the first interconnection line and the second portion of the second interconnection line, and configured to electrically connect the first interconnection line and the second interconnection line, wherein the via plug comprises a first pair of sidewalls respectively extending substantially parallel to corresponding sidewalls of the first portion and a second pair of sidewalls respectively extending substantially parallel to corresponding sidewalls of the second portion.

A manufacturing method of a semiconductor device is provided. A substrate is provided. The substrate has an active area. A plurality of word lines are formed on the substrate. Each of the word lines is extended along a first direction, and the word lines are arranged on both sides of the active area along a second direction. A first dielectric layer is formed on the substrate. The first dielectric layer covers the active area and the word lines. A contact is formed on the active area. The contact penetrates through the first dielectric layer and is electrically connected to the active area. A heating process is performed on the first dielectric layer to shrink the first dielectric layer inward, and the contact is correspondingly expanded outward.

A semiconductor element separated from an original substrate includes: an element substrate; and an element constitution part formed on the element substrate, wherein a pattern indicating a position of the semiconductor element before separating the semiconductor element from the original substrate is formed on at least one of the element substrate and the element constitution part.

A method is presented for back-end-of-the-line (BEOL) metallization with lines formed by subtractive patterning and vias formed by damascene processes. The method includes depositing a dielectric layer over a conductive layer formed over a substrate, forming spacers surrounding mandrel sections formed over the dielectric layer, selectively depositing gap fill material adjacent the spacers, selectively removing the spacers, etching the dielectric layer and the conductive layer to expose a top surface of the substrate, depositing and planarizing an inter-layer dielectric, selectively forming openings in the dielectric layer, and filling the openings with a conductive material to define metal vias.

Methods, systems, and devices for access line formation for a memory array are described. The techniques described herein may be used to fabricate access lines for one or more decks of a memory array. In some examples, one or more access lines of a deck may be formed using an independent processing step. For example, different fabrication processes may be used to form a plurality of access lines in a deck and to form the pillars (e.g., the memory cells) that are coupled with the access lines. In some examples, an offset between the access lines and the pillars may exist due to the components being fabricated in different processing steps.

A method of making a semiconductor device includes operations directed toward electrically connecting a component to a first fuse, wherein the first fuse is on a first conductive level a first distance from the component; identifying a conductive element for omission between the first fuse and a second fuse; and electrically connecting the component to the second fuse, wherein the second fuse is on a second conductive level a second distance from the component, the second distance is greater than the first distance, and the electrically connecting the component to the second fuse comprises electrically connecting the component to the second fuse without forming the identified conductive element.

The present disclosure provides a semiconductor device with a fuse structure and an anti-fuse structure and a method for forming the semiconductor device. The semiconductor device includes a first dielectric layer disposed over a semiconductor substrate, and a first electrode disposed over the first dielectric layer. The semiconductor device also includes a fuse link disposed over the first electrode, and a second electrode disposed over the fuse link. The semiconductor device further includes a third electrode disposed adjacent to the first electrode, and a second dielectric layer separating the first electrode from the first dielectric layer and the third electrode. The first electrode, the fuse link, and the second electrode form a fuse structure, and the first electrode, the third electrode, and a portion of the second dielectric layer between the first electrode and the third electrode form an anti-fuse structure.

A memory device stores data in non-volatile memory. The memory device includes a non-volatile memory array. The memory array includes tiers for accessing data stored in blocks of the memory array, including a block having a left block portion and a right block portion. A first staircase is positioned between the left block portion and the right block portion, and a bottom portion of the first staircase includes steps corresponding to first tiers of the left block portion. A second staircase is positioned between the left block portion and the right block portion, and a top portion of the second staircase includes steps corresponding to second tiers of the right block portion. The steps of the first staircase and the steps of the second staircase descend in opposite directions.

A memory device is provided. The memory device includes a substrate, a stacked structure, and a contact. The substrate includes a memory array region and a staircase region. The stacked structure is located on the substrate in the memory array region and the staircase region. The stacked structure includes a plurality of conductive layers and a plurality of insulating layers alternately stacked on each other. Each of the plurality of conductive layers includes a main body and an end part. The main body is located in the memory array region and extends to the staircase region. The end part is connected to the main body and is located in the staircase region. A thickness of the end part is greater than a thickness of the main body. The contact lands on and is connected to the end part.