A resistive memory cell includes a P-well region, an isolation structure, an N-well region, a first gate structure, a second gate structure, a first N-type doped region, a second N-type doped region, a third N-type doped region, a fourth N-type doped region, a word line, a bit line, a conductor line and a program line. The third N-type doped region, the fourth N-type doped region and the N-well region are collaboratively formed as an N-type merged region. The bit line is connected with the first N-type doped region. The word line is connected with a conductive layer of the first gate structure. The conductor line is connected with the second N-type doped region and a conductive layer of the second gate structure. The program line is connected with the N-type merged region.

The invention provides a resistive memory with better area efficiency without degrading reliability, which includes an array area, word lines, a local source line, bit lines, and a shared source line. In the array area, memory cells are arranged in a matrix, and each memory cells includes a variable resistance element and an accessing transistor. The word lines extend in a row direction of the array area and are connected to the memory cells in the row direction. The local source line extends in a column direction of the array area. The bit lines extend in the column direction and are connected to first electrodes of the memory cells in the column direction. The shared source line is connected to the local source line. The shared source line extends in the row direction and is connected to second electrodes of the memory cells in the row direction.

The present disclosure relates to a storage device comprising a memory element. The memory element may comprise a changeable physical quantity for storing information. The physical quantity may be in a drifted state. The memory element may be configured for setting the physical quantity to an initial state. Furthermore, the memory element may comprise a drift of the physical quantity from the initial state to the drifted state. The initial state of the physical quantity may be computable by means of an initialization function. The initialization function may be dependent on a target state of the physical quantity and the target state of the physical quantity may be approximately equal to the drifted state of the physical quantity.

Stochastic or near-stochastic physical characteristics of resistive switching devices are utilized for generating data distinct to those resistive switching devices. The distinct data can be utilized for applications related to electronic identification. As one example, data generated from physical characteristics of resistive switching devices on a semiconductor chip can be utilized to form a distinct identifier sequence for that semiconductor chip, utilized for verification applications for communications with the semiconductor chip or utilized for generating cryptographic keys or the like for cryptographic applications.

A resistive random-access memory (ReRAM) device may include a thermally engineered layer that is positioned adjacent to an active layer and configured to act as a heat sink during filament formation in response to applied voltages. The thermally engineered layer may act as one of the electrodes on the ReRAM device and may be adjacent to any side of the active layer. The active layer may also include a plurality of individual active layers. Each of the active layers may be associated with a different dielectric constant, such that the middle active layer has a dielectric constant that is significantly higher than the other two surrounding active layers.

Methods, systems, and devices for cleaning memory blocks using multiple types of write operations are described. A counter may be incremented each time a write command is received. In response to the counter reaching a threshold, the counter may be reset and a flag may be set. Each time a cleaning of a memory block is to take place, the flag may be checked. If the flag is set, the memory block may be cleaned using a second type of cleaning operation, such as one using a force write approach. Otherwise, the memory block may be cleaned using a first type of cleaning operation, such as one using a normal write approach. Once set, the flag may be reset after one or more memory blocks are cleaned using the second type of cleaning operation.

Methods and structures for fabricating a semiconductor device that includes a reduced programming current phase change memory (PCM) are provided. The method includes forming a bottom electrode. The method further includes forming a PCM and forming a conductive bridge filament in a dielectric to serve as a heater for the PCM. The method also includes forming a top electrode.

A programmable resistive memory element and a method of adjusting a resistance of a programmable resistive memory element are provided. The programmable resistive memory element includes at least one resistive memory element. Each resistive memory element includes an Indium-Gallium-Zinc-Oxide (IGZO) resistive layer, a first electrical contact and a second electrical contact. The first and second electrical contacts are disposed on the IGZO resistive layer in the same plane. The programmable resistive memory element includes a voltage generator coupled to the first and second electrical contacts, constructed and arranged to apply a thermal treatment to the resistive memory element to adjust a resistance of the resistive memory element.

Programming a fuse for a one-time programmable (OTP) memory can require applying a programming current for a programming period to increase a resistance of the fuse. It may be desirable for the resistance to be very high. A very high resistance may be achieved by applying a high programming current to form a void in the fuse. Applying the high programming current too long after the void is formed, however, may lead to uncontrolled variations and ultimately damage. Accordingly, it may be desirable to end the programming period sometime after the void is formed but before the uncontrolled variations begin. Ideally the programming period is ended at a time at which the programming current is minimum. The disclosed circuits and method provide a means to estimate this time without requiring the complexity of sensing very low levels of programming current.

A system includes a memory device and a processing device, operatively coupled with the memory device. The processing device is configured to perform operations that include determining a verify reference voltage associated with a logic state of a memory cell of the memory device, the verify reference voltage defining a target voltage level of a threshold voltage associated with the logic state; determining an amount of voltage compensation based on a thermal profile associated with a heat to be applied to the memory device, the thermal profile comprising a temperature associated with the heat and a period of time the heat is to be applied to the memory device; and updating the verify reference voltage using the amount of voltage compensation for an expected shift in the threshold voltage of the memory cell after the heat is applied to the memory device.