Abstract: In a non-volatile memory structure, the source/drain regions are surrounded by a nitrogen-doped region. As a result, an interface between the substrate and the charge trapping layer above the nitrogen-doped region is passivated by a plurality of nitrogen atoms. The nitrogen atoms can improve data retention, and performance of cycled non-volatile memory devices.

Abstract: A method for operating a nitride trapping memory cell is provided to resolve hard-to-erase condition by employing a reset technique to eliminate or reduce the number of electrons in the middle of a junction region. When a hard-to-erase condition is detected after a series of program and erase cycles, such as 500 or 100 program and erase cycles, a substrate transient hot hole (STHH) reset operation is applied. The substrate transient hot hole reset injects holes that are far away junction than band-to-band tunneling hot hole (BTBTHH) injection such that the STHH reset on cycle endurance is able to maintain a desirable cycle window to eliminate or reduce the hard-to erase condition in subsequent program and erase cycles.

Abstract: A method of manufacturing a flash memory device is provided. Multiple stack structures each comprising a tunneling oxide layer and a first conductive layer are formed over a substrate. Thereafter, multiple embedded doping regions is formed in the substrate between the stack structures. A dielectric layer is formed over the substrate to cover the stack structures and then the dielectric layer is etched back and a portion of dielectric layer is remained on the stack structures. Using a portion of the remaining dielectric layer as a mask, a portion of the first conductive layer is removed. An inter-layer dielectric layer and a second conductive layer are sequentially formed over the first conductive layer. Because a self-aligned process is used to define the floating gate and the floating gate has a narrow-top/wide-bottom configuration, the fabrication process is simplified and the coupling ratio of the stack gate is increased.

Abstract: Memory cells which include a semiconductor substrate having a source region and a drain region separated by a channel region; a charge-trapping structure disposed above the channel region of the semiconductor substrate; a first gate disposed above the charge-trapping structure and proximate to the source region; and a second gate disposed above the charge-trapping structure and proximate to the drain region; where the first gate and the second gate are separated by a first nanospace are provided, along with arrays including a plurality of such cells, methods of manufacturing such cells and methods of operating such cells.

Abstract: A method of stabilizing a memory device comprises trapping a plurality of electric charges in a charge trapping layer of the memory device. The charge trapping layer is positioned between a transistor control gate and a transistor channel region. The method further comprises applying a negative voltage bias to the transistor control gate. In another embodiment, the method further comprises performing a baking process on the memory device. The method further comprises performing a memory operation on the memory device.

Abstract: A MOSFET fabrication process comprises nitridation of the dielectric silicon interface so that silicon-dangling bonds are connected with nitrogen atoms creating silicon-nitrogen bonds, which are stronger than silicon-hydrogen bonds. A tunnel dielectric is formed on the substrate. A nitride layer is then formed over the tunnel dielectric layer. The top of the nitride layer is then converted to an oxide and the interface between the substrate and the tunnel dielectric is nitrided simultaneously with conversion of the nitride layer to oxide.

Abstract: A method for operating a nitride trapping memory cell is provided to resolve hard-to-erase condition by employing a reset technique to eliminate or reduce the number of electrons in the middle of a junction region. When a hard-to-erase condition is detected after a series of program and erase cycles, such as 500 or 100 program and erase cycles, a substrate transient hot hole (STHH) reset operation is applied. The substrate transient hot hole reset injects holes that are far away junction than band-to-band tunneling hot hole (BTBTHH) injection such that the STHH reset on cycle endurance is able to maintain a desirable cycle window to eliminate or reduce the hard-to erase condition in subsequent program and erase cycles.

Abstract: A method for operating a nitride trapping memory cell is provided to resolve hard-to-erase condition by employing a reset technique to eliminate or reduce the number of electrons in the middle of a junction region. When a hard-to-erase condition is detected after a series of program and erase cycles, such as 500 or 100 program and erase cycles, a substrate transient hot hole (STHH) reset operation is applied. The substrate transient hot hole reset injects holes that are far away junction than band-to-band tunneling hot hole (BTBTHH) injection such that the STHH reset on cycle endurance is able to maintain a desirable cycle window to eliminate or reduce the hard-to erase condition in subsequent program and erase cycles.

Abstract: Memory cells comprising: a semiconductor substrate having at least two source/drain regions separated by a channel region; a charge-trapping structure disposed above the channel region; and a gate disposed above the charge-trapping structure; wherein the charge-trapping structure comprises a bottom insulating layer, a first charge-trapping layer, and a second charge-trapping layer, wherein an interface between the bottom insulating layer and the substrate has a hydrogen concentration of less than about 3×1011/cm?2, and methods for forming such memory cells.

Abstract: A NAND-type flash memory device includes asymmetric floating gates overlying respective wordlines. A given floating gate is sufficiently coupled to its respective wordline such that a large gate (i.e., wordline) bias voltage will couple the floating gate with a voltage which can invert the channel under the floating gate. The inversion channel under the floating gate can thus serve as the source/drain. As a result, the memory device does not need a shallow junction, or an assist-gate. In addition, the memory device exhibits relatively low floating gate-to-floating gate (FG-FG) interference.

Abstract: A memory cell with a charge trapping structure is programmed using refill cycles that include a program pulse followed by a charge balancing pulse that causes ejection of electrons from the charge trapping structure. The refill cycle causes a blue spectrum shift in the charge trap distribution in the charge trapping structure. The algorithm includes program verify operations after the program pulse, and completes when a successful program verify operation occurs after a number of refill cycles. The charge retention properties can be greatly improved by these refill cycles.

Abstract: A non-volatile memory device on a semiconductor substrate may include a bottom oxide layer over the substrate, a middle layer of silicon nitride over the bottom oxide layer, and a top oxide layer over the middle layer. The bottom oxide layer may have a hydrogen concentration of up to 5E19 cm?3 and an interface trap density of up to 5E11 cm?2 eV?1. The three-layer structure may be a charge-trapping structure for the memory device, and the memory device may further include a gate over the structure and source and drain regions in the substrate.

Abstract: Methods of forming charge-trapping dielectric layer structures in semiconductor memory devices which comprise: (a) providing a semiconductor substrate; (b) forming an oxide layer on at least a portion of the substrate; (c) forming two or more source/drain regions in the substrate below the oxide layer; (d) re-oxidizing the oxide layer; (e) forming a charge-trapping dielectric layer on the oxide layer; and (f) forming an insulating layer on the charge-trapping dielectric layer; as well as methods which comprise: (a) providing a semiconductor substrate; (b) forming an oxide layer on at least a portion of the substrate in a dry atmosphere; (c) forming two or more source/drain regions in the substrate below the oxide layer; (d) forming a charge-trapping dielectric layer on the oxide layer; (e) forming an insulating layer on the charge-trapping dielectric layer; and (f) annealing the insulating layer in an atmosphere having a hydrogen content of less than about 0.01% are described.

Abstract: A method of manufacturing a non-volatile semiconductor memory device includes forming a sub-gate without an additional mask. A low word-line resistance is formed by a metal silicide layer on a main gate of the memory device. In operation, application of a voltage to the sub-gate forms a transient state inversion layer that serves as a bit-line, so that no implantation is required to form the bit-line.

Abstract: A memory cell with a charge trapping structure has multiple bias arrangements. Multiple cycles of applying the bias arrangements lowering and raising a threshold voltage of the memory cell leave a distribution of charge in the charge trapping layer. The charge interferes with the threshold voltage achievable in the memory cell. This distribution of charge is balanced by applying a charge balancing bias arrangement. The memory cell has a high work function gate, which causes the equilibrium state of the charge balancing bias arrangement to result in a lower threshold voltage.

Abstract: A method of fabricating a non-volatile memory device at least comprises steps as follows. First, a substrate on which a bottom dielectric layer is formed is provided. Then, impurities are introduced through the bottom dielectric layer to the substrate, so as to form a plurality of spaced doped regions on the substrate. The structure is thermally annealed for pushing the spaced doped regions to diffuse outwardly. After annealing, a charge trapping layer is formed on the bottom dielectric layer, and a top dielectric layer is formed on the charge trapping layer. Finally, a gate structure (such as a polysilicon layer and a silicide) is formed on the top dielectric layer.

Abstract: An asymmetrically doped memory cell has first and second N+ doped junctions on a P substrate. A composite charge trapping layer is disposed over the P substrate and between the first and the second N+ doped junctions. A N? doped region is positioned adjacent to the first N+ doped junction and under the composite charge trapping layer. A P? doped region is positioned adjacent to the second N+ doped junction and under the composite charge trapping layer. The asymmetrically doped memory cell will store charges at the end of the composite charge trapping layer that is above the P? doped region. The asymmetrically doped memory cell can function as an electrically erasable programmable read only memory cell, and is capable of multiple level cell operations. A method for making an asymmetrically doped memory cell is also described.

Abstract: A memory cell with a charge trapping structure has multiple bias arrangements. Multiple cycles of applying the bias arrangements lowering and raising a threshold voltage of the memory cell leave a distribution of charge in the charge trapping layer. The charge interferes with the threshold voltage achievable in the memory cell. This distribution of charge is balanced by applying a charge balancing bias arrangement at intervals during which a plurality of program and erase cycles occurs. Also, the charge balancing bias arrangement is applied prior to the beginning of program and erase cycles of the memory cell.

Abstract: A semiconductor device includes a semiconductor substrate. The semiconductor substrate includes a first inversion region, a second inversion region, and a channel region between the first inversion region and the second inversion region. The semiconductor device further includes a control gate over the channel region and at least one sub-gate over the first and second inversion regions, wherein the control gate does not extend over the at least one sub-gate.

Abstract: A non-volatile memory is provided. The memory comprises a substrate, a dielectric layer, a conductive layer, an isolation layer, a buried bit line, a tunneling dielectric layer, a charge trapping layer, a barrier dielectric layer and a word line. Wherein, the dielectric layer is disposed on the substrate. The conductive layer is disposed on the dielectric layer. The isolation layer is disposed on the substrate and adjacent to the dielectric layer and the conductive layer. The buried bit line is disposed in the substrate and underneath the isolation layer. The tunneling dielectric layer is disposed on both the substrate and the sidewalls of the conductive layer and the isolation layer. The charge trapping layer is disposed on the tunneling dielectric layer and the barrier dielectric layer is disposed on the charge trapping layer. The word line is disposed on the substrate, crisscrossing with the buried bit line.