Systems and methods for multi-wordline direct refresh operations in response to a row hammer error in a memory bank. The approach includes detecting, by a row hammer mitigation component, a row hammer error in a memory bank; and then triggering, by the row hammer mitigation component, a response to the row hammer error. Further, a memory controller receives, from a mode register, data, based on an aliasing row counter policy, selecting a type of multi-wordline direct refresh operation to be performed on a plurality of victim memory rows within the memory bank, wherein the plurality of victim memory rows are dispersed across a plurality of memory sub-banks. The approach includes concurrently executing the selected multi-wordline direct refresh operation to the plurality of victim memory rows.

Systems and methods for multi-wordline direct refresh operations in response to a row hammer error in a memory bank. The approach includes detecting, by a row hammer mitigation component, a row hammer error in a memory bank; and then triggering, by the row hammer mitigation component, a response to the row hammer error. Further, a memory controller receives, from a mode register, data, based on an aliasing row counter policy, selecting a type of multi-wordline direct refresh operation to be performed on a plurality of victim memory rows within the memory bank, wherein the plurality of victim memory rows are dispersed across a plurality of memory sub-banks. The approach includes concurrently executing the selected multi-wordline direct refresh operation to the plurality of victim memory rows.

A semiconductor memory device includes a memory cell array including a plurality of memory cell rows, a row hammer management circuit and a refresh control circuit. The row hammer management circuit counts the number of times of access associated with each of the plurality of memory cell rows in response to an active command from an external memory controller to store the counted values in each of the plurality of memory cell rows as count data, determines a hammer address associated with at least one of the plurality of memory cell rows, which is intensively accessed more than a predetermined reference number of times, based on the counted values, and performs an internal read-update-write operation. The refresh control circuit receives the hammer address and to perform a hammer refresh operation on victim memory cell rows which are physically adjacent to a memory cell row corresponding to the hammer address.

The present application provides a memory test circuit and a device wafer including the memory test circuit. The memory test circuit is coupled to a memory array having intersecting first and second signal lines, and includes a fuse element and a transistor. The fuse element has a first terminal coupled to a first group of the first signal lines and a test voltage, and has a second terminal coupled to second and third groups of the first signal lines. The transistor has a source/drain terminal coupled to the second terminal of the fuse element and another source/drain terminal coupled to a reference voltage. The first group of the first signal lines are selectively coupled to the test voltage when the transistor is turned on, and all of the first signal lines are coupled to the test voltage when the transistor is kept off.

The present application provides a memory test circuit and a device wafer including the memory test circuit. The memory test circuit is coupled to a memory array having intersecting first and second signal lines, and includes a fuse element and a transistor. The fuse element has a first terminal coupled to a first group of the first signal lines and a test voltage, and has a second terminal coupled to second and third groups of the first signal lines. The transistor has a source/drain terminal coupled to the second terminal of the fuse element and another source/drain terminal coupled to a reference voltage. The first group of the first signal lines are selectively coupled to the test voltage when the transistor is turned on, and all of the first signal lines are coupled to the test voltage when the transistor is kept off.

A media management operation is executed to write data from a source block of a cache memory to a set of pages of a destination block of a storage area of a memory sub-system. An entry of a data structure identifying a page count corresponding to the source block of the cache memory is generated. A power loss event associated with the destination block of the storage area is identified. A data recovery operation is executed using the data stored in the source block to complete the write to the destination block. The data is erased from the source block in response to the page count satisfying a condition.

The operation speed of a semiconductor device is improved. The semiconductor device includes a first memory region and a second memory region; in the semiconductor device, a first memory cell in the first memory region is superior to a second memory cell in the second memory region in data retention characteristics such as a large storage capacitance or a large channel length-channel width ratio (L/W) of a transistor. When the semiconductor device is used as a cache memory or a main memory device of a processor, the first memory region mainly stores a start-up routine and is not used as a work region for arithmetic operation, and the second memory region is used as a work region for arithmetic operation. The first memory region becomes an accessible region when the processor is booted, and the first memory region becomes an inaccessible region when the processor is in normal operation.

Apparatuses, systems, and methods for fuse based device identification. A device may include a number of fuses which are used to encode permanent information on the device. The device may receive an identification request, and may generate an identification number based on the states of at least a portion of the fuses. For example, the device may include a hash generator, which may generate the identification number by using the fuse information as a seed for a hash algorithm.

Apparatuses, systems, and methods for fuse based device identification. A device may include a number of fuses which are used to encode permanent information on the device. The device may receive an identification request, and may generate an identification number based on the states of at least a portion of the fuses. For example, the device may include a hash generator, which may generate the identification number by using the fuse information as a seed for a hash algorithm.

An apparatus includes: a semiconductor substrate; an isolation region in the semiconductor substrate, the isolation region including an isolation trench filled with an insulating material therein; a plurality of island-shaped active regions in the semiconductor substrate surrounded by the isolation region; and a buried word-line having a bottom, the buried word-line at least passing across the isolation region between the plurality of active regions; wherein the isolation trench includes upper, middle and lower portions, each of the upper and lower portions has a substantially flat surface and the middle portion has a bulged surface.