A three-dimensional semiconductor memory device includes a substrate including a peripheral circuit region and a cell array region, a plurality of peripheral gate stacks disposed in the peripheral circuit region, and an electrode structure disposed in the cell array region. The electrode structure includes a lower electrode, a lower insulating layer disposed on the lower electrode, and upper electrodes and upper insulating layers alternately stacked on the lower insulating layer. The lower insulating layer extends from the cell array region into the peripheral circuit region and covers the peripheral gate stacks. The lower insulating layer includes a first lower insulating layer and a second lower insulating layer sequentially stacked on one another. The first lower insulating layer includes a first insulating material, and the second lower insulating layer includes a second insulating material different from the first insulating material.

The disclosure relates to a semiconductor structure comprising: a first semiconductor layer, a first program transistor, and a first select transistor implementing a first antifuse cell, wherein the first semiconductor layer acts as the body of the first program transistor and as the body of the first select transistor, wherein a gate of the first program transistor and a gate of the first select transistor are on different sides of the first semiconductor layer.

A technology precluding attacks through peripheral devices thefts to a network of electronic appliances, by utilizing physical chip identification devices, is disclosed. The electronic appliances in the network are divided into the peripheral devices and the stem servers managing the registration information of the peripheral devices. The stem servers are under the central control with software, and the peripheral devices are controlled at device-level with the physical chip identification devices implemented in the chip. Thus, the security of the whole network is efficiently enhanced.

A semiconductor device includes a substrate, a peripheral structure, a lower insulating layer, and a stack. The substrate includes a peripheral circuit region and a cell array region. The peripheral structure is on the peripheral circuit region. The lower insulating layer covers the peripheral circuit region and the cell array region and has a protruding portion protruding from a flat portion. The stack is on the lower insulating layer and the cell array region, and includes upper conductive patterns and insulating patterns which are alternately and repeatedly stacked.

A semiconductor device includes a plurality of high-voltage insulated-gate field-effect transistors arranged in a matrix form on the main surface of a semiconductor substrate and each having a gate electrode, a gate electrode contact formed on the gate electrode, and a wiring layer which is formed on the gate electrode contacts adjacent in a gate-width direction to electrically connect the gate electrodes arranged in the gate-width direction. And the device includes shielding gates provided on portions of an element isolation region which lie between the transistors adjacent in the gate-width direction and gate-length direction and used to apply reference potential or potential of a polarity different from that of potential applied to the gate of the transistor to turn on the current path of the transistor to the element isolation region.

Transistors might include first and second semiconductor fins, a first source/drain region in the first semiconductor fin and extending downward from an uppermost surface of the first semiconductor fin, a second source/drain region in the second semiconductor fin and extending downward from an uppermost surface of the second semiconductor fin, a dielectric between the first and second semiconductor fins and adjacent to sidewalls of the first and second semiconductor fins, and a control gate over the dielectric and between the first and second semiconductor fins and extending to a level below upper surfaces of the first and second source/drain regions.

Some embodiments include apparatus and methods using a first diffusion region, a second diffusion region, a third diffusion region, and a fourth diffusion region; a first channel region located between a portion of the first diffusion region and a portion of the third diffusion region; a second channel region located between the portion of the third diffusion region and a portion of the second diffusion region; a third channel region located between the portion of the second diffusion region and a portion of the fourth diffusion region; and a gate located over the first, second, and third channel regions. The first and second diffusion regions are located on a first side of the gate. The third and fourth diffusion regions are located on a second side of the gate opposite from the first side.

A method for forming a semiconductor structure and a semiconductor structure are provided. The method includes following operations. A semiconductor substrate is provided. The semiconductor substrate includes an array region and a peripheral region, a plurality of conductive layers are arranged in array region and separated from each other. A support layer covering the semiconductor substrate is formed. An interconnect layer is arranged in support layer located on the array region and extends to peripheral region. The interconnect layer is electrically connected to a respective one of the conductive layers and transmits an electrical signal of the respective one of the conductive layers to the peripheral region. The support layer is patterned to form a plurality of support structures located on the peripheral region and separated from each other and an interconnect structure located on the array region and peripheral region. The interconnect layer is located in the interconnect structure.

A semiconductor memory device includes a first word line formed over a first active region. In some embodiments, a first metal line is disposed over and perpendicular to the first word line, where the first metal line is electrically connected to the first word line using a first conductive via, and where the first conductive via is disposed over the first active region. In some examples, the semiconductor memory device further includes a second metal line and a third metal line both parallel to the first metal line and disposed on opposing sides of the first metal line, where the second metal line is electrically connected to a source/drain region of the first active region using a second conductive via, and where the third metal line is electrically connected to the source/drain region of the first active region using a third conductive via.

A memory device includes a main one-time programmable (OTP) memory cell connected to a main word line and a main bit line; a redundant OTP memory cell connected to a redundant word line and a redundant bit line; and an input/output circuit configured to, during a program operation to program the main OTP memory cell and the redundant OTP memory cell, electrically separate the main bit line and the redundant bit line and form a first program current path to the main bit line and a second program current path to redundant bit line, wherein the first program current path and the second program current path are independent from each other.