Abstract: A memory device is described. Generally, the device includes a string of memory transistors, a source select transistor coupled to a first end of the string of memory transistor and a drain select transistor coupled to a second end of the string of memory transistor. Each memory transistor includes a gate electrode formed adjacent to a charge trapping layer and there is neither a source nor a drain junction between adjacent pairs of memory transistors or between the memory transistors and source select transistor or drain select transistor. In one embodiment, the memory transistors are spaced apart from adjacent memory transistors and the source select transistor and drain select transistor, such that channels are formed therebetween based on a gate fringing effect associated with the memory transistors. Other embodiments are also described.

Abstract: A memory device is described. Generally, the device includes a string of memory transistors, a source select transistor coupled to a first end of the string of memory transistor and a drain select transistor coupled to a second end of the string of memory transistor. Each memory transistor includes a gate electrode formed adjacent to a charge trapping layer and there is neither a source nor a drain junction between adjacent pairs of memory transistors or between the memory transistors and source select transistor or drain select transistor. In one embodiment, the memory transistors are spaced apart from adjacent memory transistors and the source select transistor and drain select transistor, such that channels are formed therebetween based on a gate fringing effect associated with the memory transistors. Other embodiments are also described.

Abstract: A memory device is described. Generally, the device includes a string of memory transistors, a source select transistor coupled to a first end of the string of memory transistor and a drain select transistor coupled to a second end of the string of memory transistor. Each memory transistor includes a gate electrode formed adjacent to a charge trapping layer and there is neither a source nor a drain junction between adjacent pairs of memory transistors or between the memory transistors and source select transistor or drain select transistor. In one embodiment, the memory transistors are spaced apart from adjacent memory transistors and the source select transistor and drain select transistor, such that channels are formed therebetween based on a gate fringing effect associated with the memory transistors. Other embodiments are also described.

Abstract: A memory device is described. Generally, the device includes a string of memory transistors, a source select transistor coupled to a first end of the string of memory transistor and a drain select transistor coupled to a second end of the string of memory transistor. Each memory transistor includes a gate electrode formed adjacent to a charge trapping layer and there is neither a source nor a drain junction between adjacent pairs of memory transistors or between the memory transistors and source select transistor or drain select transistor. In one embodiment, the memory transistors are spaced apart from adjacent memory transistors and the source select transistor and drain select transistor, such that channels are formed therebetween based on a gate fringing effect associated with the memory transistors. Other embodiments are also described.

Abstract: A memory device is described. Generally, the device includes a string of memory transistors, a source select transistor coupled to a first end of the string of memory transistor and a drain select transistor coupled to a second end of the string of memory transistor. Each memory transistor includes a gate electrode formed adjacent to a charge trapping layer and there is neither a source nor a drain junction between adjacent pairs of memory transistors or between the memory transistors and source select transistor or drain select transistor. In one embodiment, the memory transistors are spaced apart from adjacent memory transistors and the source select transistor and drain select transistor, such that channels are formed therebetween based on a gate fringing effect associated with the memory transistors. Other embodiments are also described.

Abstract: A memory device is described. Generally, the device includes a string of memory transistors, a source select transistor coupled to a first end of the string of memory transistor and a drain select transistor coupled to a second end of the string of memory transistor. Each memory transistor includes a gate electrode formed adjacent to a charge trapping layer and there is neither a source nor a drain junction between adjacent pairs of memory transistors or between the memory transistors and source select transistor or drain select transistor. In one embodiment, the memory transistors are spaced apart from adjacent memory transistors and the source select transistor and drain select transistor, such that channels are formed therebetween based on a gate fringing effect associated with the memory transistors. Other embodiments are also described.

Abstract: Methods and structures for forming semiconductor channels based on gate fringing effect are disclosed. In one embodiment, a NAND flash memory device comprises multiple NAND strings of memory transistors. Each memory transistor includes a charge trapping layer and a gate electrode formed on the charge trapping layer. The memory transistors are formed close to each other to form a channel between an adjacent pair of the memory transistors based on a gate fringing effect associated with the adjacent pair of the memory transistors.

Abstract: In a first method of erasing a resistive memory device, an electrical potential is applied to the gate of a transistor in series with the resistive memory device, and successive increasing currents are provided through the resistive memory device by means of providing successive increasing electrical potentials across the resistive memory device. In a second method of erasing a resistive memory device, an electrical potential is applied across the resistive memory device, and successive increasing currents are provided through the resistive memory device by means of providing successive increasing electrical potentials to the gate of a transistor in series with the resistive memory device.

Abstract: In a first method of writing data to a resistive memory device (i.e. programming or erasing), successive electrical potentials are applied across the resistive memory device, wherein the successive electrical potentials are of increasing duration. In another method of writing data to a resistive memory device (i.e. programming or erasing), an electrical potential is applied across the resistive memory device, and the level of current through the memory device is sensed as the electrical potential is applied. The application of the electrical potential is ended based on a selected level of current through the resistive memory device.

Abstract: In the method of fabricating a metal-insulator-metal (MIM) device, a first electrode of ?-Ta is provided. The Ta of the first electrode is oxidized to form a Ta2O5 layer on the first electrode. A second electrode of ?-Ta is provided on the Ta2O5 layer. Such a device exhibits strong data retention, along with resistance to performance degradation under high temperatures.

Abstract: In the method of fabricating a metal-insulator-metal (MIM) device, a first electrode of ?-Ta is provided. The Ta of the first electrode is oxidized to form a Ta2O5 layer on the first electrode. A second electrode of ?-Ta is provided on the Ta2O5 layer. Such a device exhibits strong data retention, along with resistance to performance degradation under high temperatures.

Abstract: In a first method of writing data to a resistive memory device (i.e. programming or erasing), successive electrical potentials are applied across the resistive memory device, wherein the successive electrical potentials are of increasing duration. In another method of writing data to a resistive memory device (i.e. programming or erasing), an electrical potential is applied across the resistive memory device, and the level of current through the memory device is sensed as the electrical potential is applied. The application of the electrical potential is ended based on a selected level of current through the resistive memory device.

Abstract: In a first method of erasing a resistive memory device, an electrical potential is applied to the gate of a transistor in series with the resistive memory device, and successive increasing currents are provided through the resistive memory device by means of providing successive increasing electrical potentials across the resistive memory device. In a second method of erasing a resistive memory device, an electrical potential is applied across the resistive memory device, and successive increasing currents are provided through the resistive memory device by means of providing successive increasing electrical potentials to the gate of a transistor in series with the resistive memory device.

Abstract: In the present method of programming a memory device from an erased state, the memory device includes first and second electrodes, a passive layer between the first and second electrodes, and an active layer between the first and second electrodes. In the programming method, (i) an electrical potential is applied across the first and second electrodes from higher to lower potential in one direction to reduce the resistance of the memory device, and (ii) an electrical potential is applied across the first and second electrodes from higher to lower potential in the other direction to further reduce the resistance of the memory device.