Apparatus and methods are described to reduce program disturb for a memory string with a partial select gate drain, which is partially cut by a shallow trench. The memory string with a partial select gate drain is linked with a neighboring full select gate drain that during its programming can cause a program disturb in the memory string with a partial select gate drain. The bias voltage applied to the selected full select gate drain can be controlled from a high state for low memory program states to a lower state for the high memory program states. The high data states may cause program disturb. The reduction in the bias voltage can match a reduction in the bias voltage applied to the bit lines to reduce the program disturb while providing adequate signal to program the high states on the memory string of the full select gate drain.

A data receiving device of a memory device comprises a first pre-amplifier configured to receive previous data, a first reference voltage, and input data, and to output differential signals by comparing the input data with the first reference voltage in response to a clock, when the first pre-amplifier is selected in response to the previous data, a second pre-amplifier configured to receive inverted previous data, a second reference voltage, different from the first reference voltage, and the input data, and outputting a common signal in response to the clock, when the second pre-amplifier is unselected in response to the previous data; and an amplifier configured to receive the differential signals and the common signal, and to latch the input data by amplifying the differential signals.

A data receiving device of a memory device comprises a first pre-amplifier configured to receive previous data, a first reference voltage, and input data, and to output differential signals by comparing the input data with the first reference voltage in response to a clock, when the first pre-amplifier is selected in response to the previous data, a second pre-amplifier configured to receive inverted previous data, a second reference voltage, different from the first reference voltage, and the input data, and outputting a common signal in response to the clock, when the second pre-amplifier is unselected in response to the previous data; and an amplifier configured to receive the differential signals and the common signal, and to latch the input data by amplifying the differential signals.

A semiconductor memory structure includes a semiconductor layer, a conductive layer disposed over the semiconductor layer, a gate penetrating through the conductive layer and the semiconductor layer, and an interposing layer disposed between the gate and the conductive layer and between the gate and the semiconductor layer, wherein a pair of channel regions is formed in the semiconductor layer at two sides of the gate.

Aspects of the disclosure provide a memory device. For example, the memory device can include a memory array, a bitline and a buffer. The memory array can include a plurality of memory strings. The memory strings can be divided into a first memory string group and a second memory string group. The bitline can include a first bitline segment coupled to the first memory string group and a second bitline segment coupled to the second memory string group. The first bitline segment can be disposed between the first memory string group and the buffer and be connected to the buffer through a first conduction path. The second bitline segment can be disposed between the second memory string group and the buffer and be connected to the buffer through a second conduction path.

Aspects of the disclosure provide a memory device. For example, the memory device can include a memory array, a bitline and a buffer. The memory array can include a plurality of memory strings. The memory strings can be divided into a first memory string group and a second memory string group. The bitline can include a first bitline segment coupled to the first memory string group and a second bitline segment coupled to the second memory string group. The first bitline segment can be disposed between the first memory string group and the buffer and be connected to the buffer through a first conduction path. The second bitline segment can be disposed between the second memory string group and the buffer and be connected to the buffer through a second conduction path.

The present technology relates to an electronic device. A memory device that controls a voltage applied to each line to prevent or mitigate a channel negative boosting phenomenon during a sensing operation includes a memory block connected to a plurality of lines, a peripheral circuit configured to perform a sensing operation on selected memory cells connected to a selected word line among the plurality of lines, and control logic configured to control voltages applied to drain select lines, source select lines, and word lines between the drain select lines and the source select lines among the plurality of lines, during the sensing operation and an equalizing operation performed after the sensing operation. The control logic controls a voltage applied to an unselected drain select line according to whether a cell string is shared with a selected drain select line among the drain select lines, during the sensing operation.

A semiconductor device includes a cell region and a peripheral circuit region. The cell region includes gate electrode layers stacked on a substrate, channel structures extending in a first direction, extending through the gate electrode layers, and connected to the substrate, and bit lines extending in a second direction and connected to the channel structures above the gate electrode layers. The peripheral circuit region includes page buffers connected to the bit lines. Each page buffer includes a first and second elements adjacent to each other in the second direction and sharing a common active region between a first gate structure of the first element and a second gate structure of the second element in the second direction. Boundaries of the common active region include an oblique boundary extending in an oblique direction forming an angle between 0 and 90 degrees with the second direction.

A semiconductor device includes a cell region and a peripheral circuit region. The cell region includes gate electrode layers stacked on a substrate, channel structures extending in a first direction, extending through the gate electrode layers, and connected to the substrate, and bit lines extending in a second direction and connected to the channel structures above the gate electrode layers. The peripheral circuit region includes page buffers connected to the bit lines. Each page buffer includes a first and second elements adjacent to each other in the second direction and sharing a common active region between a first gate structure of the first element and a second gate structure of the second element in the second direction. Boundaries of the common active region include an oblique boundary extending in an oblique direction forming an angle between 0 and 90 degrees with the second direction.

A semiconductor memory device includes a memory block including plurality of string groups, a peripheral circuit, and control logic. The peripheral circuit performs a program operation on source select transistors included in the memory block. The control logic controls the program operation of the peripheral circuit. Each of the plurality of string groups includes at least one cell string, and the at least one cell string includes inner source select transistors located adjacent to memory cells and outer source select transistors located adjacent to a common source line. The control logic controls the peripheral circuit to perform program operations on the outer source select transistors and the inner source select transistors by an ISPP method. The control logic controls the peripheral circuit to perform a verify operation by dividing the inner source select transistors into at least two groups during the program operation of the inner source select transistors.