A variety of applications can include apparatus having a memory device with an array of vertical strings of memory cells for the memory device with data lines coupled to the vertical strings, where the data lines have been formed by a metal liner deposition process. In the metal liner deposition, a metal can be formed on a patterned dielectric region. The metal liner deposition process allows for construction of the height of the data lines to be well controlled with selection of a thickness for the dielectric region used in forming the metal liner. Use of a metal liner deposition provides a controlled mechanism to reduce data line capacitance by being able to select liner thickness in forming the data lines. The use of the dielectric region with the metal liner deposition can allow the fabrication of the data lines to avoid pitch double or pitch quad processes.

A variety of applications can include apparatus having a memory device with an array of vertical strings of memory cells for the memory device with data lines coupled to the vertical strings, where the data lines have been formed by a metal liner deposition process. In the metal liner deposition, a metal can be formed on a patterned dielectric region. The metal liner deposition process allows for construction of the height of the data lines to be well controlled with selection of a thickness for the dielectric region used in forming the metal liner. Use of a metal liner deposition provides a controlled mechanism to reduce data line capacitance by being able to select liner thickness in forming the data lines. The use of the dielectric region with the metal liner deposition can allow the fabrication of the data lines to avoid pitch double or pitch quad processes.

A semiconductor device includes active regions extending in a first direction on a substrate; a gate electrode intersecting the active regions on the substrate, extending in a second direction, and including a contact region protruding upwardly; and an interconnection line on the gate electrode and connected to the contact region, wherein the contact region includes a lower region having a first width in the second direction and an upper region located on the lower region and having a second width smaller than the first width in the second direction, and wherein at least one side surface of the contact region in the second direction has a point at which an inclination or a curvature is changed between the lower region and the upper region.

An integrated circuit includes a substrate, an interconnection part, and an isolating region located between the substrate and the interconnection part. A decoy structure is located within the isolating region and includes a silicided sector which is electrically isolated from the substrate.

An integrated circuit includes a substrate, an interconnection part, and an isolating region located between the substrate and the interconnection part. A decoy structure is located within the isolating region and includes a silicided sector which is electrically isolated from the substrate.

A method is disclosed, including the following operations: arranging a first gate structure extending continuously above a first active region and a second active region of a substrate; arranging a first separation spacer disposed on the first gate structure to isolate an electronic signal transmitted through a first gate via and a second gate via that are disposed on the first gate structure, in which the first gate via and the second gate via are arranged above the first active region and the second active region respectively; and arranging a first local interconnect between the first active region and the second active region, in which the first local interconnect is electrically coupled to a first contact disposed on the first active region and a second contact disposed on the second active region.

A method is disclosed, including the following operations: arranging a first gate structure extending continuously above a first active region and a second active region of a substrate; arranging a first separation spacer disposed on the first gate structure to isolate an electronic signal transmitted through a first gate via and a second gate via that are disposed on the first gate structure, in which the first gate via and the second gate via are arranged above the first active region and the second active region respectively; and arranging a first local interconnect between the first active region and the second active region, in which the first local interconnect is electrically coupled to a first contact disposed on the first active region and a second contact disposed on the second active region.

Embodiments of three-dimensional (3D) memory devices having through array contacts (TACs) and methods for forming the same are disclosed. In an example, a 3D memory device includes a substrate, a memory stack on the substrate comprising a plurality of conductor/dielectric layer pairs, a channel structure extending vertically through the conductor/dielectric layer pairs in the memory stack, a TAC extending vertically through the conductor/dielectric layer pairs in the memory stack, and a dummy channel structure filled with a dielectric layer and extending vertically through the conductor/dielectric layer pairs in the memory stack.

The present disclosure provides a method for fabricating an integrated circuit (IC). The method includes receiving an IC layout having active regions, conductive contact features landing on the active regions, and a conductive via feature to be landing on a first subset of the conductive contact features and to be spaced from a second subset of the conductive contact features; evaluating a spatial parameter of the conductive via feature to the conductive contact features; and modifying the IC layout according to the spatial parameter such that the conductive via feature has a S-curved shape.

A circuit board with improved heat dissipation function and a method for manufacturing the circuit board are provided. The method includes providing a first metal layer defining a first slot; forming a first adhesive layer in the first slot; electroplating copper on each first pillar to form a first heat conducting portion; forming a first insulating layer on the first adhesive layer having the first heat conducting portion, and defining a first blind hole in the first insulating layer; filling the first blind hole with thermoelectric separation metal to form a second heat conducting portion; forming a first wiring layer on the first insulating layer; forming a second insulating layer on the first wiring layer, defining a second blind hole on the second insulating layer; electroplating copper in the second blind hole to form a third heat conducting portion; mounting an electronic component on the second insulating layer.