According to one embodiment, a memory device includes a nonvolatile memory, a volatile memory, a controller, and a board. The nonvolatile memory stores data. The volatile memory holds a part of the data stored in the nonvolatile memory. The memory controller controls the volatile memory and the nonvolatile memory. The nonvolatile memory, the volatile memory, and the memory controller are provided on the board. The memory controller transmits an interrupt signal to a request source, when the volatile memory does not have any data corresponding to an address which the request source requests to access.

An integrated circuit (IC) device may include a single substrate that includes a single chip, and a plurality of memory cells spaced apart from one another on the substrate and having different structures. Manufacturing the IC device may include forming a plurality of first word lines in a first region of the substrate, and forming a plurality of second word lines in or on a second region of the substrate. Capacitors may be formed on the first word lines. Source lines may be formed on the second word lines. An insulation layer that covers the plurality of capacitors and the plurality of source lines may be formed in the first region and the second region. A variable resistance structure may be formed at a location spaced apart from an upper surface of the substrate by a first vertical distance, in the second region.

A memory device includes a substrate including first and second regions, the first region having first wordlines and first bitlines, and the second region having second wordlines and second bitlines, a first memory cell array including first memory cells in the first region, the first memory cell array having volatility, and each of the first memory cells including a cell switch having a first channel region adjacent to a corresponding first wordline of the first wordlines, and a capacitor connected to the cell switch, and a second memory cell array including second memory cells in the second region, the second memory cell array having non-volatility, and each of the second memory cells including a second channel region adjacent to a corresponding second wordline of the second wordlines, and a ferroelectric layer between the corresponding second wordline of the second wordlines and the second channel region.

An integrated circuit (IC) device includes a first terminal, a second terminal, a resistive memory device configured to have a first resistance level in a first state and a second resistance level in a second state, and a switching device including a control terminal and a current path. The resistive memory device and the current path are coupled in series between the first and second terminals, and the switching device is configured to, responsive to a first voltage level at the control terminal, control the current path to have a first conductance level in a first programmed state and a second conductance level in a second programmed state.

Embodiments of three-dimensional (3D) memory devices with a 3D NAND memory array having a plurality of pages, an on-die cache coupled to the memory array on a same chip and configured to cache a plurality of batches of program data between a host and the memory array, the on-die cache having SRAM cells, and a controller coupled to the on-die cache on the same chip. The controller is configured to check a status of an (N−2).sup.th batch of program data, N being an integer equal to or greater than 2, program an (N−1).sup.th batch of program data into respective pages in the 3D NAND memory array, and cache an N.sup.th batch of program data in respective space in the on-die cache as a backup copy of the N.sup.th batch of program data.

Powering random access memory (RAM) modules with non-volatile memory components may include providing, by a power supply, a first output voltage to one or more RAM modules, each RAM module of the one or more RAM modules comprising a volatile memory component and a non-volatile memory component; providing, by the power supply, a second output voltage to one or more system components distinct from the one or more RAM modules; detecting a power event; sending, by the power supply, in response to detecting the power event, a signal to the one or more RAM modules to initiate a save operation, wherein the save operation comprises storing, for each of the one or more RAM modules, data from the volatile memory component to the non-volatile memory component; and ceasing, by the power supply, the second output voltage while maintaining the first output voltage to facilitate the save operation.

A method includes determining, via status polling at a first interval, an indicator of an almost ready status of a set of memory cells of a memory device, based on the indicator of the almost ready status, determining the set of memory cells of the memory device is almost ready to complete execution of an operation on the set of memory cells of the memory device, and responsive to determining the set of memory cells of the memory device is almost ready to complete execution of the operation, performing status polling at a second interval.

Embodiments of semiconductor devices and fabrication methods thereof are disclosed. In an example, first semiconductor structures are formed. At least one of the first semiconductor structures includes a processor, static random-access memory (SRAM) cells, and a first bonding layer comprising first bonding contacts. Second semiconductor structures are formed. At least one of the second semiconductor structures comprises dynamic random-access memory (DRAM) cells and a second bonding layer comprising second bonding contacts. The first semiconductor structures and the second semiconductor structures are bonded. The first bonding contacts of the first semiconductor structure are in contact with the second bonding contacts of the second semiconductor structure. At least one of the first semiconductor structures and the second semiconductor structures further includes a peripheral circuit.

A semiconductor memory device has a NOR-type memory cell array, a crossbar array, an entry gate, and a column selecting/signal processing unit. The crossbar array has a plurality of rows and columns, variable resistor elements formed in intersections of rows and columns respectively. The entry gate arranged between the memory cell array and the crossbar array, connects a selected bit line of the memory cell array to the crossbar array based on a selection signal. The column selecting/signal processing unit has a column writing unit, a column reading unit, and a NOR writing unit. The column writing unit writes data read from the memory cell array to a selected column of the crossbar array. The column reading unit reads data of the selected column of the crossbar array. The NOR writing unit at least writes data read by the column writing unit to the memory cell array.

An integrated circuit, a system, and a method to integrate phase change memory and magnetoresistive random access memory within a same integrated circuit in a system. The integrated circuit may include an MRAM and a PCM. The MRAM may include an MRAM bottom electrode, an MRAM stack, and an MRAM top electrode. The PCM may include a PCM bottom electrode, where the PCM bottom electrode has a lower height than the MRAM bottom electrode, a phase change material, and a PCM top electrode.