A non-volatile memory includes a cell array, a current supply circuit, a path selecting circuit, a verification circuit and a control circuit. During a sample period of a verification action, the control circuit controls the current supply circuit to provide n M-th reference currents to the verification circuit and convert the n M-th reference currents into n reference voltages. During a verification period of the verification action, the control circuit controls n multi-level memory cells of a selected row of the cell array to generate n cell currents to the verification circuit and convert the n cell currents into n sensed voltages. The n verification devices generate the n verification signals according to the reference voltages and the sensed voltages. Accordingly, the control circuit judges whether the n multi-level memory cells have reached an M-th storage state.

According to one embodiment, a semiconductor storage device includes a first memory cell, a second memory cell, a first transistor, a second transistor, and a third transistor. The first transistor includes a first portion electrically connected to a first circuit, a second portion electrically connected to the first memory cell, and a first gate electrode installed between the first portion and the second portion. The second transistor includes a third portion electrically connected to the first circuit, a fourth portion electrically connected to the second memory cell, and a first gate electrode installed between the third portion and the fourth portion. The third transistor includes the second portion, the fourth portion, a fifth portion electrically connected to a second circuit, and a second gate electrode installed between the second portion and the fifth portion and between the fourth portion and the fifth portion.

Apparatus might include an array of memory cells and a controller to perform access operations on the array of memory cells. The controller might be configured to establish a negative potential in a body of a memory cell of the array of memory cells, and initiate a sensing operation on the memory cell while the body of the memory cell has the negative potential. Apparatus might further include an array of memory cells, a timer, and a controller to perform access operations on the array of memory cells. The controller might be configured to advance the timer, and establish a negative potential in a body of a memory cell of the array of memory cells in response to a value of the timer having a desired value.

A 3D memory device may include a first set of memory layers, a second set of memory layers above the first set of memory layers, and a first dummy memory layer between the first and second memory layers. The 3D memory device may include a plurality of NAND memory strings each extending through the first and second set of memory layers and the first dummy memory layer. The 3D memory device may include a word line (WL) driving circuit that, when programming one of the first set of memory layers, may be configured to apply a second pre-charge voltage to the first dummy memory layer during the pre-charge period. The second pre-charge voltage may overlap with the first pre-charge voltage and ramp down prior to the first pre-charge voltage.

A method can include receiving a request to read data from a memory cell of a memory device coupled with the processing device, determining a voltage distribution parameter value associated with the memory cell, determining a set of read levels associated with the voltage distribution parameter value, wherein each read level in the determined set of read levels corresponds to a respective voltage distribution of the memory cell, and reading, using the determined set of read levels, data from the memory cell. The voltage distribution parameter value can be determined by identifying a particular voltage distribution of the memory cell by sampling the memory cell at a plurality of voltage levels, and determining the voltage distribution parameter value based on the particular voltage distribution. The voltage distribution parameter value can be a voltage value that is included in the particular voltage distribution.

Three-dimensional (3D) memory devices with 3D phase-change memory (PCM) and methods for forming and operating the 3D memory devices are disclosed. In an example, a 3D memory device includes a first semiconductor structure including an array of NAND memory cells, and a first bonding layer including first bonding contacts. The 3D memory device also further includes a second semiconductor structure including a second bonding layer including second bonding contacts, a semiconductor layer and a peripheral circuit and an array of PCM cells between the second bonding layer and the semiconductor layer. The 3D memory device further includes a bonding interface between the first and second bonding layers. The first bonding contacts are in contact with the second bonding contacts at the bonding interface.

A circuit for performing energy-efficient and high-throughput multiply-accumulate (MAC) arithmetic dot-product operations and convolution computations includes a two dimensional crossbar array comprising a plurality of row inputs and at least one column having a plurality of column circuits, wherein each column circuit is coupled to a respective row input. Each respective column circuit includes an excitatory memristor neuron circuit having an input coupled to a respective row input, a first synapse circuit coupled to an output of the excitatory memristor neuron circuit, the first synapse circuit having a first output, an inhibitory memristor neuron circuit having an input coupled to the respective row input, and a second synapse circuit coupled to an output of the inhibitory memristor neuron circuit, the second synapse circuit having a second output. An output memristor neuron circuit is coupled to the first output and second output of each column circuit and has an output.

A circuit for performing energy-efficient and high-throughput multiply-accumulate (MAC) arithmetic dot-product operations and convolution computations includes a two dimensional crossbar array comprising a plurality of row inputs and at least one column having a plurality of column circuits, wherein each column circuit is coupled to a respective row input. Each respective column circuit includes an excitatory memristor neuron circuit having an input coupled to a respective row input, a first synapse circuit coupled to an output of the excitatory memristor neuron circuit, the first synapse circuit having a first output, an inhibitory memristor neuron circuit having an input coupled to the respective row input, and a second synapse circuit coupled to an output of the inhibitory memristor neuron circuit, the second synapse circuit having a second output. An output memristor neuron circuit is coupled to the first output and second output of each column circuit and has an output.

A semiconductor storage device includes a memory transistor and a word line connected to a gate electrode of the memory transistor. When a write sequence is interrupted before a k+1.sup.th verification operation is ended after a k.sup.th verification operation is ended in the n.sup.th write loop of the write sequence, a voltage equal to or higher than a verification voltage corresponding to a first verification operation in the n.sup.th write loop is supplied to the word line before start of the k+1.sup.th verification operation after resumption of the write sequence. A time from the resumption of the write sequence to the start of the k+1.sup.th verification operation is shorter than a time from start of the first verification operation to end of the k.sup.th verification operation in the n.sup.th write loop.

A processing device of a memory sub-system is configured to identify a read level of a plurality of read levels associated with a voltage bin of a plurality of voltage bins of a memory device; assign a first threshold voltage offset to the read level of the voltage bin; assign a second threshold voltage offset to the read level of the voltage bin; perform, on block associated with the read level, a first operation of a first operation type using the first threshold voltage offset; and perform, on the blocks associated with the read level, a second operation of a second operation type using the second threshold voltage offset.