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.

Memory devices might include a first latch to store a first data bit; a second latch to store a second data bit; a data line selectively connected to the first latch, the second latch, and a string of series-connected memory cells; and a controller configured to bias the data line during a programing operation of a selected memory cell. The controller may with the first data bit equal to 0 and the second data bit equal to 0, bias the data line to a first voltage level; with the first data bit equal to 1 and the second data bit equal to 0, bias the data line to a second voltage level; with the first data bit equal to 0 and the second data bit equal to 1, bias the data line to a third voltage level; and with the first data bit equal to 1 and the second data bit equal to 1, bias the data line to a fourth voltage level.

A memory die includes an alternating stack of insulating layers and electrically conductive layers through which memory opening fill structures vertically extend. The memory die includes at least three memory array regions interlaced with at least two contact regions, or at least three contact regions interlaced with at least two memory array regions in the same memory plane. A logic die including at least two word line driver regions can be bonded to the memory die. The interlacing of the contact regions and the memory array regions can reduce lateral offset of boundaries of the word line driver regions from boundaries of the contact regions.

A memory die includes an alternating stack of insulating layers and electrically conductive layers through which memory opening fill structures vertically extend. The memory die includes at least three memory array regions interlaced with at least two contact regions, or at least three contact regions interlaced with at least two memory array regions in the same memory plane. A logic die including at least two word line driver regions can be bonded to the memory die. The interlacing of the contact regions and the memory array regions can reduce lateral offset of boundaries of the word line driver regions from boundaries of the contact regions.

An electronic device, and more particularly, a page buffer is provided. The page buffer includes a sensing node configured to sense a potential of a bit line coupled to a memory cell, a precharging circuit coupled to the sensing node and configured to precharge a potential of the sensing node to a first voltage during an evaluation operation on the memory cell, a discharging circuit coupled to the sensing node and configured to discharge the potential of the sensing node from the first voltage to a second voltage, and a latch circuit coupled to the discharging circuit and configured to store therein data sensed from the memory cell based on a result of comparing the potential of the sensing node with a reference voltage after the potential of the sensing node is discharged to the second voltage and a predetermined period elapses.

An electronic device, and more particularly, a page buffer is provided. The page buffer includes a sensing node configured to sense a potential of a bit line coupled to a memory cell, a precharging circuit coupled to the sensing node and configured to precharge a potential of the sensing node to a first voltage during an evaluation operation on the memory cell, a discharging circuit coupled to the sensing node and configured to discharge the potential of the sensing node from the first voltage to a second voltage, and a latch circuit coupled to the discharging circuit and configured to store therein data sensed from the memory cell based on a result of comparing the potential of the sensing node with a reference voltage after the potential of the sensing node is discharged to the second voltage and a predetermined period elapses.

Apparatuses and techniques are described for programming memory cells with a reduced number of program pulses. A program operation includes a first, foggy program pass followed by a second, fine program pass. The number of program loops in the foggy program pass is minimized while providing relatively narrow Vth distributions for the foggy states. The program loops include one or more checkpoint program loops in which a program speed of the memory cells is determined through a read operation. In a next program loop, the fast-programming memory cells are inhibited from programming while the slow-programming memory cells are programmed with a reduced speed by applying a program speed-reducing bit line voltage. This brings the threshold voltage of the slow-programming memory cells into alignment with the threshold voltage of the fast-programming memory cells.

Apparatuses and techniques are described for programming memory cells with a reduced number of program pulses. A program operation includes a first, foggy program pass followed by a second, fine program pass. The number of program loops in the foggy program pass is minimized while providing relatively narrow Vth distributions for the foggy states. The program loops include one or more checkpoint program loops in which a program speed of the memory cells is determined through a read operation. In a next program loop, the fast-programming memory cells are inhibited from programming while the slow-programming memory cells are programmed with a reduced speed by applying a program speed-reducing bit line voltage. This brings the threshold voltage of the slow-programming memory cells into alignment with the threshold voltage of the fast-programming memory cells.

A memory device configured to perform a program operation and a backup operation together includes a memory block including a main sub block including selected memory cells in which program data is programmed among a plurality of memory cells respectively connected to a plurality of word lines, and a backup block in which page data included in the program data is backed up, a peripheral circuit configured to perform a plurality of program loops to program the program data in the selected memory cells, and control logic configured to control the peripheral circuit to back up any one of the page data while programming the selected memory cells in preset program loops among the plurality of program loops.

A memory device configured to perform a program operation and a backup operation together includes a memory block including a main sub block including selected memory cells in which program data is programmed among a plurality of memory cells respectively connected to a plurality of word lines, and a backup block in which page data included in the program data is backed up, a peripheral circuit configured to perform a plurality of program loops to program the program data in the selected memory cells, and control logic configured to control the peripheral circuit to back up any one of the page data while programming the selected memory cells in preset program loops among the plurality of program loops.