A circuit including a die and an integrated passive device. The die includes a first substrate and at least one active device. The integrated passive device includes a first layer, a second substrate, a second layer and an inductance. The inductance includes vias, where the vias are implemented in the second substrate. The inductance is implemented on the first layer, the second substrate, and the second layer. A resistivity per unit area of the second substrate is greater than a resistivity per unit area of the first substrate. The third layer is disposed between the die and the integrated passive device. The third layer includes pillars, where the pillars respectively connect ends of the inductance to the at least one active device. The die, the integrated passive device and the third layer are disposed relative to each other to form a stack.

Various embodiments of the present application are directed a memory layout for reduced line loading. In some embodiments, a memory device comprises an array of bit cells, a first conductive line, a second conductive line, and a plurality of conductive bridges. The first and second conductive lines may, for example, be source lines or some other conductive lines. The array of bit cells comprises a plurality of rows and a plurality of columns, and the plurality of columns comprise a first column and a second column. The first conductive line extends along the first column and is electrically coupled to bit cells in the first column. The second conductive line extends along the second column and is electrically coupled to bit cells in the second column. The conductive bridges extend from the first conductive line to the second conductive line and electrically couple the first and second conductive lines together.

A semiconductor device includes transistors on a substrate, a first interlayer insulating layer on the transistors, a lower interconnection line in an upper portion of the first interlayer insulating layer, an etch stop layer on the first interlayer insulating layer and the lower interconnection line, a second interlayer insulating layer on the etch stop layer, an upper interconnection line in the second interlayer insulating layer, the upper interconnection line including a via portion penetrating the etch stop layer to contact the lower interconnection line, and an etch stop pattern on the etch stop layer and in contact with a first sidewall of the via portion. The second interlayer insulating layer extends on the etch stop pattern and a top surface of the etch stop layer free of the etch stop pattern. A dielectric constant of the etch stop pattern is higher than a dielectric constant of the etch stop layer.

The present disclosure relates to an integrated chip that uses a metal strap to improve performance and reduce electromigration by coupling a middle-end-of-the-line (MEOL) layer to a power rail. In some embodiments, the integrated chip has an active area with a plurality of source/drain regions. The active area contacts a MEOL structure extending in a first direction. A first metal wire extends in a second direction, which is perpendicular to the first direction, at a location overlying the MEOL structure. A metal strap extending in a first direction is arranged over the first metal wire. The metal strap is configured to connect the first metal line to a power rail (e.g., which may be held at a supply or ground voltage), which extends in the second direction. By connecting the MEOL structure to the power rail by way of a metal strap, parasitic capacitance and electromigration may be reduced.

Semiconductor devices and methods of forming the same are provided. In one embodiment, a semiconductor device includes a gate structure sandwiched between and in contact with a first spacer feature and a second spacer feature, a top surface of the first spacer feature and a top surface of the second spacer feature extending above a top surface of the gate structure, a gate self-aligned contact (SAC) dielectric feature over the first spacer feature and the second spacer feature, a contact etch stop layer (CESL) over the gate SAC dielectric feature, a dielectric layer over the CESL, a gate contact feature extending through the dielectric layer, the CESL, the gate SAC dielectric feature, and between the first spacer feature and the second spacer feature to be in contact with the gate structure, and a liner disposed between the first spacer feature and the gate contact feature.

A device is provided. The device may include one or more of a package base, a substrate, a die secured to the substrate, a plurality of bond connections, and a package lid. The package base includes a plurality of package leads and a package base body. The package base body includes an open cavity disposed through the entire package base body, a plurality of package bond pads, disposed within a periphery of the open cavity, and a mounting shelf, disposed within the open cavity. The substrate is secured to the mounting shelf, and includes a plurality of substrate bond pads. The plurality of bond connections are configured to provide electrical connections between one or more of the die, the substrate bond pads, and the package bond pads. The package lid is secured over the open cavity to the package base body.

A method according to the present disclosure includes receiving a workpiece including a gate structure, a first source/drain (S/D) feature, a second S/D feature, a first dielectric layer over the gate structure, the first S/D feature, the second S/D feature, a first S/D contact over the first S/D feature, a second S/D contact over the second S/D feature, a first etch stop layer (ESL) over the first dielectric layer, and a second dielectric layer over the first ESL, forming a S/D contact via through the second dielectric layer and the first ESL to couple to the first S/D contact, forming a gate contact opening through the second dielectric layer, the first ESL, and the first dielectric layer to expose the gate structure, and forming a common rail opening adjoining the gate contact opening to expose the second S/D contact, and forming a common rail contact in the common rail opening.

The present application discloses a semiconductor device with a landing pad of conductive polymer and a method for fabricating the semiconductor device. The semiconductor device includes a substrate, a dielectric layer disposed over the substrate, a plug disposed in the dielectric layer, and a landing pad of conductive polymer disposed over the dielectric layer. The method includes: providing a substrate; forming a dielectric layer with a plug over the substrate; performing an etching process to remove a portion of the dielectric layer to expose a protruding portion of the plug; forming a conductive polymer layer covering the dielectric layer and the protruding portion; and performing a thermal process to form a landing pad over the dielectric layer in a self-aligned manner. The landing pad of conductive polymer comprises a protruding portion of the plug, a first silicide layer disposed over the protruding portion, and a second silicide layer disposed on a sidewall of the protruding portion.

A semiconductor structure includes a metal gate structure disposed over a semiconductor substrate, a gate spacer disposed on a sidewall of the metal gate structure, an source/drain contact disposed over the semiconductor substrate and separated from the metal gate structure by the gate spacer, and a contact feature coupling the metal gate structure to the source/drain contact. The contact feature may be configured to include a dielectric layer disposed on a metal layer, where the dielectric layer and the metal layer are defined by continuous sidewalls.

Dual damascene interconnect structures with fully aligned via integration schemes are formed using different dielectric materials having different physical properties. A low-k dielectric material having good fill capabilities fills nanoscopic trenches in such structures. Another dielectric material forms the remainder of the dielectric portion of the interconnect layer and has good reliability properties, though not necessarily good trench filling capability. The nanoscopic trenches may be filled with a flowable polymer using flowable chemical vapor deposition. A further dielectric layer having good reliability properties is deposited over the metal lines and dual damascene patterned to form interconnect line and via patterns. The patterned dielectric layer is filled with interconnect metal, thereby forming interconnect lines and fully aligned via conductors. The via conductors are electrically connected to previously formed metal lines below.