Abstract: A method for manufacturing an electrically programmable non-volatile memory cell comprises forming a first electrode on a substrate, forming an inter-electrode layer of material on the first electrode having a property which is characterized by progressive change in response to stress, and forming a second electrode over the inter-electrode layer of material. The inter-electrode layer comprises a dielectric layer, such as ultra-thin oxide, between the first and second electrodes. A programmable resistance, or other property, is established by stressing the dielectric layer, representing stored data. Embodiments of the memory cell are adapted to store multiple bits of data per cell and/or adapted for programming more than one time without an erase process.

Abstract: A method for programming a memory array is provided. The memory array includes a memory cell string composed of a first transistor, a plurality of memory cells and a second transistor connected in series, and the method for programming the memory array includes following steps. In a setup phase, a switching memory cell in the memory cells is turned off, and a first voltage and a second voltage are applied to a first source/drain and a second source/drain of the switching memory cell. In a programming phase, a bit line connected to the memory cell string is floating, and a ramp signal is provided to a word line electrically connected to the switching memory cell.

Abstract: A memory device is described, including a gate over a substrate, a gate dielectric between the gate and the substrate, and two charge storage layers. The width of the gate is greater than that of the gate dielectric, so that two gaps are present at both sides of the gate dielectric and between the gate and the substrate. Each charge storage layer includes a body portion in one of the gaps, a first extension portion connected with the body portion and protruding out of the corresponding sidewall of the gate, and a second extension portion connected to the first extension portion and extending along the sidewall of the gate, wherein the edge of the first extension portion protrudes from the sidewall of the second extension portion.

Abstract: A memory device is described, including a tunnel dielectric layer over a substrate, a gate over the tunnel dielectric layer, at least one charge storage layer between the gate and the tunnel dielectric layer, two doped regions in the substrate beside the gate, and a word line that is disposed on and electrically connected to the gate and has a thickness greater than that of the gate.

Abstract: A memory structure having a memory cell including a first dielectric layer, a gate, a semiconductor layer, a first doped region, a second doped region and a charge storage layer is provided. The first dielectric layer is on the substrate. The gate includes a base portion on the first dielectric layer and a protruding portion disposed on the base portion and partially exposing the base portion. The semiconductor layer is conformally disposed on the gate, and includes a top portion over the protruding portion, a bottom portion over the base portion exposed by the protruding portion and a side portion located at a sidewall of the protruding portion and connecting the top and bottom portions. The first and second doped regions are respectively in the top and bottom portions. The side portion serves as a channel region. The charge storage layer is between the gate and the semiconductor layer.

Abstract: A memory and a manufacturing method thereof are provided. A plurality of stacked structures extending along a first direction is formed on a substrate. Each of the stacked structures includes a plurality of first insulating layers and a plurality of second insulating layers. The first insulating layers are stacked on the substrate and the second insulating layers are respectively disposed between the adjacent first insulating layers. A plurality of trenches extending along the first direction is formed in each of the stacked structures. The trenches are respectively located at two opposite sides of each of the second insulating layers. A first conductive layer is filled in the trenches. A plurality of charge storage structures extending along a second direction is formed on the stacked structures and a second conductive layer is formed on each of the charge storage structures.

Abstract: A non-volatile memory and a manufacturing method thereof are provided. A first oxide layer having a protrusion is formed on a substrate. A pair of doped regions is formed in the substrate at two sides of the protrusion. A pair of charge storage spacers is formed on the sidewalls of the protrusion. A second oxide layer is formed on the first oxide layer and the charge storage spacers. A conductive layer is formed on the second oxide layer.

Abstract: A memory device includes a plurality of memory cells arranged in series in the semiconductor body, such as a NAND string, having a plurality of word lines. A selected memory cell is programmed by hot carrier injection. The program operation is based on metering a flow of carriers between a first semiconductor body region on a first side of the selected cell in the NAND string and a second semiconductor body region on a second side of the selected cell. A program potential higher than a hot carrier injection barrier level is applied to the selected cell, and then the drain to source voltage across the selected cell and the flow of carriers in the selected cell reach a level sufficient to support hot carrier injection, which is controlled by a combination of a switch cell adjacent the selected cell and modulation of a source side voltage applied to the NAND string.

Abstract: Disclosed is a memory device and method of operation thereof. The memory device may include a source region and a drain region of a first dopant type, the source and drain regions contain a first semiconductor material; a body region of a second dopant type, the body region being sandwiched between the source and drain regions, the body comprising a second semiconductor material; a gate dielectric layer over at least the body region; and a gate comprising a conductive material over the gate dielectric layer. Specifically, one of the first semiconductor material and the second semiconductor material is lattice matched with the other of the first semiconductor material and the second semiconductor material and has an energy gap smaller than the energy gap of the other of the first semiconductor material and the second semiconductor material.

Abstract: An integrated circuit includes a memory cell structure including a first cell and a second cell. The first cell includes a first storage structure and a first gate over a substrate. The first gate is over the first storage structure. The second cell includes a second storage structure and a second gate over the substrate. The second gate is over the second storage structure. The first gate is separated from the second gate. A first doped region is adjacent to the first cell and is coupled to a first source. A second doped region is configured within the substrate and adjacent to the second cell. The second doped region is coupled to a second source. At least one third doped region is between the first cell and the second cell, wherein the third doped region is floating.

Abstract: A multi-Level Cell (MLC) can be used to store, for example, 4 bits per cell by storing two bits on each of two sides. Each side can store, e.g., four different current level states that can be determined by the number of holes injected into, e.g., nitride layer, during programming. As more holes are injected the current decreases for a given voltage. The current can be low, therefore, it can be advantageous in one embodiment to use a current amplifier. The current amplifier can be a BJT, MOS or other type of device.

Abstract: A memory structure including a memory cell is provided, and the memory cell includes following elements. A first gate is disposed on a substrate. A stacked structure includes a first dielectric structure, a channel layer, a second dielectric structure and a second gate disposed on the first gate, a first charge storage structure disposed in the first dielectric structure and a second charge storage structure disposed in the second dielectric structure. At least one of the first charge storage structure and the second charge storage structure includes two charge storage units which are physically separated. A first dielectric layer is disposed on the first gate at two sides of the stacked structure. A first source and drain and a second source and drain are disposed on the first dielectric layer and located at two sides of the channel layer.

Abstract: A method for erasing a memory array is provided. The memory array comprises a plurality of memory cell strings, and each of the memory cell strings comprises a plurality of memory cells connected to a plurality of word lines. The method for erasing the memory array includes the following steps. A first voltage is applied to a substrate of the memory array. A second voltage is applied to a word line of a selected memory cell, and a plurality of passing voltages are applied to other word lines. And, a third voltage and a fourth voltage are respectively applied to a first source/drain region and a second source/drain region of the selected memory cell, so that a band to band (BTB) hot hole injecting method is induced to erase the specific memory cell, wherein the third voltage is not equal to the fourth voltage.

Abstract: A method of programming a memory is provided. The memory has a first cell, having a first S/D region and a second S/D region shared with a second cell. The second cell has a third S/D region opposite to the second S/D region. When programming the first cell, a first voltage is applied to a control gate of the first cell, a second voltage is applied to a control gate of the second cell to slightly turn on a channel of the second cell, a third and a fourth voltage are respectively applied to the first and the third S/D regions, and the second S/D region is floating. A carrier flows from the third S/D region to the first S/D region, and is injected into a charge storage layer of the first cell by source-side injection.

Abstract: A multi-Level Cell (MLC) can be used to store, for example, 4 bits per cell by storing two bits on each of two sides. Each side can store, e.g., four different current level states that can be determined by the number of holes injected into, e.g., nitride layer, during programming. As more holes are injected the current decreases for a given voltage. The current can be low, therefore, it can be advantageous in one embodiment to use a current amplifier. The current amplifier can be a BJT, MOS or other type of device.

Abstract: An integrated circuit includes a memory array having a plurality of memory cells arranged in rows and columns, each memory cell including two doped regions and a channel region therebetween, each pair of adjacent memory cells sharing a common doped region, each memory cell having a charge storage member over the channel region and a control gate over the charge storage member. A first word line is coupled to the memory cells in the same row, each of the memory cells designated as the Nth memory cell. Each of a plurality of bit lines is designated as the Nth bit line, the Nth bit line coupled to a doped region shared by the Nth memory cell and the (N?1)th memory cell. The integrated circuit also has a plurality of global bit lines, each of which coupled to two of the bit lines via a switch.

Abstract: A memory device includes a plurality of memory cells arranged in series in the semiconductor body, such as a NAND string, having a plurality of word lines. A selected memory cell is programmed by hot carrier injection. The program operation is based on metering a flow of carriers between a first semiconductor body region on a first side of the selected cell in the NAND string and a second semiconductor body region on a second side of the selected cell. A program potential higher than a hot carrier injection barrier level is applied to the selected cell, and then the drain to source voltage across the selected cell and the flow of carriers in the selected cell reach a level sufficient to support hot carrier injection, which is controlled by a switch cell adjacent the selected cell.

Abstract: The invention provides a memory array. The memory array comprises a substrate, a plurality of word lines, a charge trapping structure, a plurality of trench channels and a plurality of bit lines. The word lines are located over the substrate and the word lines are parallel to each other. The charge trapping structure covers a surface of each of the word lines. The trench channels are located over the substrate and the word lines and the trench channels are alternatively arranged and each trench channel is separated from the adjacent word lines by the charge trapping structure. The bit lines are located over the word lines and each bit line is across over each of the word lines and each trench channel is electrically coupled to the bit lines.

Abstract: A method for programming a first memory cell in a memory array. In a specific embodiment, each memory cell has a drain, a source, a channel, and a control gate overlying a charge storage material and the channel. The source of the first memory cell is coupled to the drain of a second memory cell. A voltage is applied to the drain of the first memory cell, and the source of the second memory cell is grounded. The method includes floating the drain of the second memory cell and the source of the first memory cell and turning on the channels of the first and second memory cells, effectively forming an extended channel region. Hot carriers are injected to the charge storage material of the first cell to program the first memory cell. The extended channel lowers electrical fields and reduces punch through leakage in unselected memory cells.

Abstract: A non-volatile memory including a substrate, a stacked gate structure, two doped regions and a plurality of spacers is provided. The stacked gate structure is disposed on the substrate, wherein the stacked gate structure includes a first dielectric layer, a charge storage layer, a second dielectric layer and a conductive layer in sequence from bottom to top relative to the substrate. The doped regions are disposed in the substrate at two sides of the stacked gate structure, respectively, and bottom portions of the doped regions contact with the substrate under the doped regions. The spacers are respectively disposed between each side of each of the doped regions and the substrate, and top portions of the spacers are lower than top portions of the doped regions.