A semiconductor structure is disclosed that includes a first conductive line, a first conductive segment, a second conductive segment, and a gate. The first conductive segment is electrically coupled to the first conductive line through a conductive via. The second conductive segment is configured to electrically couple the first conductive segment with a third conductive segment disposed over an active area. The gate is disposed under the second conductive segment and disposed between first conductive segment and the third conductive segment. The first conductive line and the second conductive segment are disposed at two sides of the conductive via respectively. A length of the first conductive segment is greater than a length of the third conductive segment.

An embodiment is an integrated circuit structure including a static random access memory (SRAM) cell having a first number of semiconductor fins, the SRAM cell having a first boundary and a second boundary parallel to each other, and a third boundary and a fourth boundary parallel to each other, the SRAM cell having a first cell height as measured from the third boundary to the fourth boundary, and a logic cell having the first number of semiconductor fins and the first cell height.

A package structure including IPD and method of forming the same are provided. The package structure includes a die, an encapsulant laterally encapsulating the die, a first RDL structure disposed on the encapsulant and the die, an IPD disposed on the first RDL structure and an underfill layer. The IPD includes a substrate, a first connector on a first side of the substrate and electrically connected to the first RDL structure, a guard structure on a second side of the substrate opposite to the first side and laterally surrounding a connector region, and a second connector disposed within the connector region and electrically connected to a conductive via embedded in the substrate. The underfill layer is disposed to at least fill a space between the first side of the IPD and the first RDL structure. The underfill layer is separated from the connector region by the guard structure.

An integrated circuit includes a high-voltage MOS (HV) transistor and a capacitor supported by a semiconductor substrate. A gate stack of the HV transistor includes a first insulating layer over the semiconductor layer and a gate electrode formed from a first polysilicon. The capacitor includes a first electrode made of the first polysilicon and a second electrode made of a second polysilicon and at least partly resting over the first electrode. A first polysilicon layer deposited over the semiconductor substrate is patterned to form the first polysilicon of the gate electrode and first electrode, respectively. A second polysilicon layer deposited over the semiconductor substrate is patterned to form the second polysilicon of the second electrode. Silicon oxide spacers laterally border the second electrode and the gate stack of the HV transistor. Silicon nitride spacers border the silicon oxide spacers.

The present disclosure provides a semiconductor device comprising: a block separator including a semiconductor film and a multi-layered insulating film, wherein the multi-layered insulating film surrounds the semiconductor film; memory block stacks divided from each other by the block separator, each memory block stack including interlayer insulating films and conductive patterns alternately stacked, wherein the conductive patterns are coupled to memory cells; and channel structures passing through the memory block stacks and electrically coupled to the memory cells.

An integrated circuit including a link or string of semiconductor memory cells, wherein each memory cell includes a floating body region for storing data. The link or string includes at least one contact configured to electrically connect the memory cells to at least one control line, and the number of contacts in the string or link is the same as or less than the number of memory cells in the string or link.

An integrated circuit process includes the following steps. A substrate including a first area and a second area is provided. A plurality of line patterns cover the substrate of the first area, and a sacrificial line pattern covers the substrate of the second area, wherein these line patterns separate from and are orthogonal to the sacrificial line pattern. The present invention also provides an integrated circuit formed by said process. A substrate includes a first area and a second area; a plurality of line patterns cover the substrate of the first area; a slot pattern is in the substrate of the second area, wherein these line patterns are orthogonal to the slot pattern. Additionally, a plurality of line patterns cover the substrate; a sacrificial line pattern is at ends of the line patterns, wherein these line patterns separate from and are orthogonal to the sacrificial line pattern.

Techniques are disclosed herein for ferroelectric-based field-effect transistors (FETs) with threshold voltage (VT) switching for enhanced RF switch transistor on-state and off-state performance. Employing a ferroelectric gate dielectric layer that can switch between two ferroelectric states enables a higher VT during the transistor off-state (VT,hi) and a lower VT during the transistor on-state (VT,lo). Accordingly, the transistor on-state resistance (Ron) can be maintained low due to the available relatively high gate overdrive (Vg,on−VT,lo) while still handling a relatively high maximum RF power in the transistor off-state due to the high VT,hi −Vg,off value. Thus, the Ron of an RF switch transistor can be improved without sacrificing maximum RF power, and/or vice versa, the maximum RF power can be improved without sacrificing the Ron. A ferroelectric layer (e.g., including Hf.sub.xZr.sub.yO) can be formed between a transistor gate dielectric layer and gate electrode to achieve such benefits.

The invention provides a semiconductor package and a method for fabricating a base for a semiconductor package. The semiconductor package includes a conductive trace embedded in a base. A semiconductor device is mounted on the conductive trace via a conductive structure.

A semiconductor structure includes a first conductive line, a first conductive segment, a second conductive segment, and a third conductive segment. The first conductive segment is electrically coupled to the first conductive line. The second conductive segment is electrically coupled the first conductive segment. The second conductive segment is disposed between the first conductive segment and the third conductive segment. A top surface of the first conductive segment is aligned with a top surface of the second conductive segment in a same layer.