A semiconductor device includes an active area extending in a first direction, a first transistor including a first gate electrode and first source and drain areas disposed on the active area, the first source and drain areas being disposed at opposite sides of the first gate electrode, a second transistor including a second gate electrode and second source and drain areas disposed on the active area, the second source and drain areas being disposed at opposite sides of the second gate electrode, and a third transistor including a third gate electrode and third source and drain areas disposed on the active area, the third source and drain areas being disposed at opposite sides of the third gate electrode, and the first gate electrode, the second gate electrode, and the third gate electrode extending in a second direction different from the first direction. The second transistor is configured to turn on and off, based on an operation mode of the semiconductor device.

The current disclosure is directed to a SRAM bit cell having a reduced coupling capacitance. In a vertical direction, a wordline “WL” and a bitline “BL” of the SRAM cell are stacked further away from one another to reduce the coupling capacitance between the WL and the BL. In an embodiment, the WL is vertically spaced apart from the BL with one or more metallization level that none of the WL or the BL is formed from. Connection island structures or jumper structures are provided to connect the upper one of the WL or the BL to the transistors of the SRAM cell.

A semiconductor device according to the present disclosure includes a gate-all-around (GAA) transistor in a first device area and a fin-type field effect transistor (FinFET) in a second device area. The GAA transistor includes a plurality of vertically stacked channel members and a first gate structure over and around the plurality of vertically stacked channel members. The FinFET includes a fin-shaped channel member and a second gate structure over the fin-shaped channel member. The fin-shaped channel member includes semiconductor layers interleaved by sacrificial layers.

A semiconductor device including a static random access memory (SRAM) device includes a first SRAM array including a first plurality of bit cells arranged in a matrix; a second SRAM array including a second plurality of bit cells arranged in a matrix; and a plurality of abutting dummy cells disposed between the first SRAM array and the second SRAM array. Each of the plurality of abutting dummy cells includes a plurality of dummy gate electrode layers and a plurality of dummy contacts. The semiconductor device further includes a first-type well continuously extending from the first SRAM array to the second SRAM array. The first-type well is in direct contact with portions of the plurality of dummy contacts.

A memory device includes a first plurality of program lines of a first group, a second plurality of program lines of a second group, and a plurality of address lines. The second plurality of program lines are disposed next to and are parallel to the first plurality of program lines. The plurality of address lines are coupled to the first plurality of program lines and the second plurality of program lines respectively. The plurality of address lines are twisted and are intersected with the first plurality of program lines and the second plurality of program lines in a layout view. At least two adjacent program lines of the first plurality of program lines or the second plurality of program lines have lengths different from each other. A method is also disclosed herein.

A memory device includes a plurality of memory cells located in a first region of the memory device. The memory cells include a first signal line, a first circuit located in the first region of the memory device, and a plurality of logic circuits located in a second region of the memory device. The second region and the first region have different design rules. The first circuit is configured to be selectively enabled and disabled. When the first circuit is enabled, the first signal line is electrically coupled in parallel with a second signal line.

Structures and methods for the co-optimization of core (logic) devices and SRAM devices include a semiconductor device having a logic portion and a memory portion. In some embodiments, a logic device is disposed within the logic portion. In some cases, the logic device includes a single fin N-type FinFET and a single fin P-type FinFET. In some examples, a static random-access memory (SRAM) device is disposed within the memory portion. The SRAM device includes an N-well region disposed between two P-well regions, where the two P-well regions include an N-type FinFET pass gate (PG) transistor and an N-type FinFET pull-down (PD) transistor, and where the N-well region includes a P-type FinFET pull-up (PU) transistor.

A 3D semiconductor device, the device including: a first single crystal layer including a plurality of first transistors; at least one first metal layer disposed above the plurality of first transistors; a second metal layer disposed above the at least one first metal layer; a plurality of second transistors disposed atop the second metal layer; a plurality of third transistors disposed atop the plurality of second transistors; a plurality of fourth transistors disposed atop the plurality of third transistors; a third metal layer disposed above the plurality of fourth transistors; a fourth metal layer disposed above the third metal layer; and a plurality of connecting metal paths from the fourth metal layer or the third metal layer to the second metal layer, where the device includes an array of memory cells, and where at least one of the memory cells includes one of the plurality of third transistors.

To provide a semiconductor device which can be stably operated while achieving a reduction of the power consumption. A semiconductor device includes a CPU, a system controller which designates an operation speed of the CPU, P-type SOTB transistors, and N-type SOTB transistors. The semiconductor device is provided with an SRAM which is connected to the CPU, and a substrate bias circuit which is connected to the system controller and is capable of supplying substrate bias voltages to the P-type SOTB transistors and the N-type SOTB transistors. Here, when the system controller designates a low speed mode to operate the CPU at a low speed, the substrate bias circuit supplies the substrate bias voltages to the P-type SOTB transistors and the N-type SOTB transistors.

The control circuit of the semiconductor device initializes a plurality of memory cells. The method is that when the reset signal is at a high level, the control circuit turns off the first transistor, selects multiple word lines, turns off the precharge circuit, turns on the write column switch, and turns off the read column switch. Then, the control circuit initializes a plurality of memory cells by setting the first bit line to the low level and the second bit line to the high level by the writing circuit.