Abstract: A method of operating a memory cell for 3D array of this invention is described as follows. Carriers of a first type are injected into a charge storage layer of the memory cell by applying a double-side biased (DSB) voltage to double sides of the memory cell. Carriers of a second type are injected into the charge storage layer by applying FN voltages.

Abstract: A memory applicable to an embedded memory is provided. The memory includes a substrate, a gate, a charge-trapping gate dielectric layer, a source, and a drain. The gate is disposed above the substrate. The charge-trapping gate dielectric layer is disposed between the gate and the substrate. The source and the drain are disposed in the substrate beside the gate respectively.

Abstract: A method for manufacturing a non-volatile memory is provided. The method comprises steps of providing a substrate. Thereafter, a plurality of first doped regions are formed in the substrate and then a plurality of trenches are formed in a portion of the first doped regions. A plurality of second doped regions are formed in a portion of the substrate under the bottoms of the trenches respectively. Then, a charge storage layer is formed conformal to a surface of the substrate and a conductive layer is formed over the substrate, wherein the conductive layer covers the charge storage layer and fills in the trenches.

Abstract: Methods are described for improving the retention of a memory device by execution of a retention improvement procedure. The retention improvement procedure comprises a baking process of the memory device in a high temperature environment, a verifying process of the memory device that checks the logic state of memory cells, and a reprogramming process to program the memory device once again by programming memory cells in a 0-state to a high-Vt state. The baking step of placing the memory device in a high temperature environment causes a charge loss by expelling shallow trapped charges, resulting in the improvement of retention reliability.

Abstract: A method of operating a non-volatile memory cell is described, including pre-erasing the cell through double-side biased (DSB) injection of a first type of carrier and programming the cell through Fowler-Nordheim (FN) tunneling of a second type of carrier.

Abstract: A non-volatile VG memory array employing memory semiconductor cells capable of storing two bits of information having a non-conducting charge trapping dielectric, such as silicon nitride, layered in associating with at least one electrical insulating layer, such as an oxide, is disclosed. Bit lines of the memory array are capable of transmitting positive voltage to reach the source/drain regions of the memory cells of the array. A method that includes the hole injection erasure of the memory cells of the array that lowers the voltage threshold of the memory cells to a value lower than the initial voltage threshold of the cells is disclosed. The hole injection induced lower voltage threshold reduces the second bit effect such that the window of operation between the programmed and un-programmed voltage thresholds of the bits is widened. The programming and read steps reduce leakage current of the memory cells in the array.

Abstract: A NAND based memory device uses inversion bit lines in order to eliminate the need for implanted bit lines. As a result, the cell size can be reduced, which can provide greater densities in smaller packaging. In another aspect, a method for fabricating a NAND based memory device that uses inversion bit lines is disclosed.

Abstract: A virtual ground array structure uses inversion bit lines in order to eliminate the need for implanted bit lines. As a result, the cell size can be reduced, which can provide greater densities and smaller packaging.

Abstract: The present invention describes a uniform program method and a uniform erase method of a charge trapping memory by employing a substrate transient hot electron technique for programming, and a substrate transient hot hole technique for erasing, which emulate an FN tunneling method for NAND memory operation. The methods of the present invention are applicable to a wide variety of charge trapping memories including n-channel or p-channel SONOS types of memories and floating gate (FG) type memories. the programming of the charge trapping memory is conducted using a substrate transient hot electron injection in which a body bias voltage Vb has a short pulse width and a gate bias voltage Vg has a pulse width that is sufficient to move electrons from a channel region to a charge trapping structure.

Abstract: A method for programming and erasing a PHINES memory device is comprising providing one or more additional pulses that are associated with a program or erase pulse, wherein the additional pulses are of similar polarity, but of lesser magnitude than the program or erase pulses. For an erase pulse on a PHINES memory device, two additional pulses can be utilized. For a program pulse on the source-side of a PHINES memory device, one additional pulse can be utilized that comprises a negative bias measured from a gate of the memory device to a source of the memory device. For a program pulse on the drain-side of a PHINES memory device, one additional pulse can be utilized that comprises a negative bias measured from a gate of the memory device to a drain of the memory device.

Abstract: Methods are described for improving the retention of a memory device by execution of a retention improvement procedure. The retention improvement procedure comprises a baking process of the memory device in a high temperature environment, a verifying process of the memory device that checks the logic state of memory cells, and a reprogramming process to program the memory device once again by programming memory cells in a 0-state to a high-Vt state. The baking step of placing the memory device in a high temperature environment causes a charge loss by expelling shallow trapped charges, resulting in the improvement of retention reliability.

Abstract: The present invention describes a uniform program method and a uniform erase method of a charge trapping memory by employing a substrate transient hot electron technique for programming, and a substrate transient hot hole technique for erasing, which emulate an FN tunneling method for NAND memory operation. The methods of the present invention are applicable to a wide variety of charge trapping memories including n-channel or p-channel SONOS types of memories and floating gate (FG) type memories. the programming of the charge trapping memory is conducted using a substrate transient hot electron injection in which a body bias voltage Vb has a short pulse width and a gate bias voltage Vg has a pulse width that is sufficient to move electrons from a channel region to a charge trapping structure.

Abstract: A memory array comprises a semiconductor substrate, two-bit memory cells, word lines, a gate voltage source, bit lines and bit line control cells. The memory cells have a first and a second source/drain regions, each memory cell includes a dielectric trapping layer, and the dielectric trapping layer is disposed between a first oxide layer and a gate layer. The word lines are coupled to the gate layer. The gate voltage source is coupled to the word lines and configured to apply erase voltages between 14 and 20 volts to the word lines. The bit lines are in electrical communication with the first and the second source/drain regions. The bit line control cells are disposed at the beginning and end of each bit line, the bit line control cells are configured to control the electrical communication of each bit line with the first and the second source/drain regions.

Abstract: A phase change memory device with a memory element including a basis phase change material, such as a chalcogenide, and one or more additives, where the additive or additives have a non-constant concentration profile along an inter-electrode current path through a memory element. The use of “non-constant” concentration profiles for additives enables doping the different zones with different materials and concentrations, according to the different crystallographic, thermal and electrical conditions, and different phase transition conditions.

Abstract: Phase change memory devices and methods for operating described herein are based on the discovery that, following an initial high current operation applied to a phase change memory cell to establish the high resistance reset state, the current-voltage (I-V) behavior of the memory cell under different bias voltages can be used to detect if the memory cell is a defect cell having poor data retention characteristics.

Abstract: A non-volatile memory cell may include a semiconductor substrate; a source region in a portion of the substrate; a drain region within a portion of the substrate; a well region within a portion of the substrate. The memory cell may further include a first carrier tunneling layer over the substrate; a charge storage layer over the first carrier tunneling layer; a second carrier tunneling layer over the charge storage layer; and a conductive control gate over the second carrier tunneling layer. Specifically, the drain region is spaced apart from the source region, and the well region may surround at least a portion of the source and drain regions. In one example, the second carrier tunneling layer provides hole tunneling during an erasing operation and may include at least one dielectric layer.

Abstract: A memory structure that combines embedded flash memory and PPROM. The PPROM can be used as a memory structure. The flash memory can be used, e.g., as air replacement cells or back up memory, or additional memory cells. The PPROM cells are stacked on top of the flash memory cells and the PPROM density can be increased by implementing three-dimensional PPROM structures.

Abstract: Methods are described for improving the retention of a memory device by execution of a retention improvement procedure. The retention improvement procedure comprises a baking process of the memory device in a high temperature environment, a verifying process of the memory device that checks the logic state of memory cells, and a reprogramming process to program the memory device once again by programming memory cells in a 0-state to a high-Vt state. The baking step of placing the memory device in a high temperature environment causes a charge loss by expelling shallow trapped charges, resulting in the improvement of retention reliability.

Abstract: A method of identifying logical information in a cell, particularly in a programming by hot hole injection nitride electron storage (PHINES) cell by one-side reading scheme is disclosed. The method comprise steps of: erasing the first region and the second region of PHINES cell by increasing a local threshold voltage (Vt) to a certain value; programming at least one of the first region and the second region of the PHINES cell by hot hole injection; and reading a logical state of the PHINES cell by measuring an output current of one of the first region and the second region; wherein different quantity of the output current is caused by interaction between different quantity of the hot hole stored in the first region and the second region, so as to determine the logical state of the PHINES cell by one-side reading scheme.

Abstract: An operating method of a memory array is provided. The operating method includes performing a programming operation. The programming operation is performed by applying a first voltage to a bit line of the memory array and a second voltage to a plurality of word lines of the memory array to cause simultaneously programming a plurality of selected memory cells in the memory array.