Abstract: An electronic fuse (“E-fuse”) has a silicide filament link extending along a gap between polysilicon structures formed on a silicon substrate. The silicide filament link extends across diffusions formed in the gap. A P-N junction between terminals of the E-fuse provides high resistivity after programming (fusing) the silicide filament link.

Abstract: A nonvolatile semiconductor memory comprises: a semiconductor substrate; a first gate electrode formed on a surface of the semiconductor substrate through a first gate insulating film; a second gate electrode formed on the surface of the semiconductor substrate through a second gate insulating film and being adjacent to the first gate electrode through an insulating film; a charge trapping film formed at least in a trap region surrounded by the semiconductor substrate, the first gate electrode and the second gate electrode; and a tunnel insulating film formed between the charge trapping film and the second gate electrode. In one of programming and erasing, electrons are injected into the charge trapping film from the second gate electrode through the tunnel insulating film by Fowler-Nordheim tunneling.

Abstract: A non-volatile memory is provided. The non-volatile memory comprises at least a silicon-on-insulator transistor including a substrate; an insulating layer disposed on the substrate; an active region disposed on the insulating layer; and an energy barrier device disposed in the active region and outputting a relatively small current when the non-volatile memory is read.

Abstract: A nonvolatile semiconductor memory device includes: a semiconductor substrate including a first channel, and a source region and a drain region provided on both sides of the first channel; a first insulating film provided on the first channel; a charge retention layer provided on the first insulating film; a second insulating film provided on the charge retention layer; and a semiconductor layer including a second channel provided on the second insulating film, and a source region and a drain region provided on both sides of the second channel.

Abstract: A clock signal generation circuit into which a first clock signal and a control signal based on an address are inputted, and a second clock signal based on said first clock signal is generated after a lapse of predetermined time from said input of the control signal.

Abstract: A nonvolatile semiconductor memory device comprises: a plurality of first memory strings; a first select transistor having one end thereof connected to one end of the first memory strings; a first line commonly connected to the other end of a plurality of the first select transistors; a switch circuit having one end thereof connected to the first line; and a second line commonly connected to the other end of a plurality of the switch circuits. The switch circuit controls electrical connection between the second line and the first line.

Abstract: A nonvolatile semiconductor memory device includes: a memory unit; and a control unit. The memory unit includes a multilayer structure including electrode films and inter-electrode insulating films alternately stacked in a first direction; a semiconductor pillar piercing the multilayer structure in the first direction; a memory layer provided between the semiconductor pillar and the electrode films; a inner insulating film provided between the memory layer and the semiconductor pillar; a outer insulating film provided between the memory layer and the electrode films; and a wiring electrically connected to the first semiconductor pillar. In erasing operation, the control unit sets the first wiring at a first potential and sets the electrode film at a second potential lower than the first potential, and then sets the first wiring at a third potential and sets the electrode film at a fourth potential higher than the third potential.

Abstract: The memory comprises at least two data storage units using hot carrier stressing damage to store data. Each data storage unit comprises the first terminal, the second terminal and a third terminal. When the first cross voltage between the second and third terminals is higher than the first threshold voltage and the second cross voltage between the first and third terminals is higher than the second threshold voltage, the data storage unit is in the first writing operation.

Abstract: The present invention provides a semiconductor memory device having a capacitor electrode of a MOS capacitor formed in polygon and slanting faces enlarged toward an insulating film are provided therearound. A floating gate electrode is provided which extends from over a channel region of a MOSEFT to over corners of ends on the MOSFET side, of the capacitor electrode and which is opposite to the channel region and the capacitor electrode with a gate insulating film interposed therebetween.

Abstract: An integrated circuit and a design structure are disclosed. An integrated circuit may comprise: a data retaining device; a partially depleted silicon-on-insulator (PD SOI) device electrically coupled to the data retaining device; and a measurement device coupled to the PD SOI device for measuring a state of the PD SOI device indicating a body voltage thereof, the measuring device being communicatively coupled to a calculating means which determines a history state of a data in the data retaining device based on the measured state of the PD SOI device.

Abstract: A nonvolatile semiconductor memory includes a transistor, a first MOS, a second MOS, a first voltage circuit, and a second voltage circuit. The transistor includes a accumulation layer, a control gate, and a first impurity diffused layer. The first MOS includes a first electrode and a second layer. The second MOS includes a second electrode and a third layer, after the channels being formed, the first MOS and the second MOS being cut off. The first voltage circuit applies a first voltage to an active region to generate a forward bias. The second voltage circuit applies a second voltage, and a third voltage to the control gate of the transistor, after the first voltage circuit charges the first to third impurity diffused layer to the first voltage, the second voltage circuit applying the second voltage and the third voltage to the control gate of the transistor.

Abstract: A non-volatile semiconductor storage device includes a control circuit performing an erase operation to erase data from a selected one of memory transistors. The control circuit applies a first voltage to the other end of selected one of selection transistors, causes the selected one of the selection transistors to turn on, and causes any one of the memory transistors to turn on that is closer to the selection transistor than the selected one of the memory transistors. The control circuit also applies a second voltage lower than the first voltage to a gate of the selected one of the memory transistors. Such a potential difference between the first voltage and the second voltage causing a change in electric charges in the electric charge storage layer.

Abstract: A memory circuit includes a latch having a first node and a second node, a MIS transistor having a gate node, a first source/drain node coupled to the first node of the latch, and a second source/drain node, and a control circuit configured to control the gate node and second source/drain node to make a lingering change in a threshold voltage of the MIS transistor in a first operation and to cause the latch in a second operation to store data responsive to whether a lingering change in the threshold voltage is present, wherein the MIS transistor includes diffusion regions, a gate electrode, and sidewalls, wherein a metallurgical junction of each of the diffusion regions is positioned under the gate electrode, and a lateral boundary of a depletion layer in the diffusion region serving as a drain is positioned under a corresponding one of the sidewalls in the first operation.

Abstract: One time programmable memory devices are disclosed that are programmed using hot carrier induced degradation to alter one or more transistors characteristics. A one time programmable memory device is comprised of an array of transistors. Transistors in the array are selectively programmed using hot carrier induced changes in one or more transistor characteristics, such as changes to the saturation current, threshold voltage or both, of the transistors. The changes to the transistor characteristics are achieved in a similar manner to known hot carrier transistor aging principles. The disclosed one time programmable memory devices are small and programmable at low voltages and small current.

Abstract: Embodiments of an apparatus and methods for providing improved flash memory cell characteristics are generally described herein. Other embodiments may be described and claimed.

Abstract: A semiconductor device includes a semiconductor region, a tunnel insulating film formed on the semiconductor region, a charge-storage insulating film formed on the tunnel insulating film, a block insulating film formed on the charge-storage insulating film, and a control gate electrode formed on the block insulating film, wherein the tunnel insulating film comprises a first region which is formed on a surface of the semiconductor region and contains silicon and oxygen, a second region which contains silicon and nitrogen, a third region which is formed on a back surface of the charge-storage insulating film and contains silicon and oxygen, and an insulating region which is formed at least between the first region and the second region or between the second region and the third region, and contains silicon and nitrogen and oxygen and the second region is formed between the first region and the third region.

Abstract: In a nonvolatile memory cell with charge trapping dielectric (150), the tunnel dielectric (140) includes chlorine adjacent to the charge trapping dielectric but no chlorine (or less chlorine) adjacent to the cell's channel region (120). The chlorine adjacent to the charge trapping dielectric serves to improve the programming and/or erase speed. The low chlorine concentration adjacent to the channel region prevents chlorine from degrading the data retention. Other features are also provided.

Abstract: A method of programming a memory cell (100), the method comprising applying a first electric potential to a first electric terminal (101) of the memory cell (100) to accelerate first charge carriers of a first type of conductivity to thereby generate second charge carriers of a second type of conductivity by impact ionisation of the accelerated first charge carriers, and applying a second electric potential to a second electric terminal (102) of the memory cell (100) to accelerate the second charge carriers to thereby inject the second charge carriers in a charge trapping structure (103) of the memory cell (100).

Abstract: A nonvolatile memory device includes a word line group including a plurality of middle word lines and an edge word line having charge storage patterns on a substrate. A peripheral line is disposed on one side of the word line group so that the edge word line is between the peripheral word line and the middle word lines. The peripheral line includes an insulating layer and a gate electrode. Charge storage patterns of the middle and edge word lines are separated from each other, and a charge storage pattern of the edge word line extends on one side to be connected to the insulating layer of the peripheral line. Methods of forming nonvolatile memory devices are also disclosed.

Abstract: A nonvolatile memory device with nanowire channel and a method for fabricating the same are proposed, in which side etching is used to shrink side walls of a side-gate to form a nanowire pattern, thereby fabricating a nanowire channel on the dielectric of the side walls of the side-gate. A nonvolatile memory device with nanowire channel and dual-gate control can thus be achieved. This nonvolatile memory device can enhance data writing and erasing efficiency, and also has the capability of low voltage operation. Moreover, through a process of low cost and easy steps, highly reproducible and mass producible fabrication of nanowire devices can be accomplished.

Abstract: In reading data from a memory cell, a determining circuit determines whether a received voltage value is within at least one first voltage range through a one-time read operation using a semiconductor device that senses an output current corresponding to the received voltage value. The at least one first voltage range includes a first upper limit voltage value and a first lower limit voltage value. A data value of the memory cell is set as a first data value when the received voltage value is within the specific voltage range.

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 nonvolatile semiconductor memory includes a memory cell, a first gate control circuit that is coupled to the memory cell, and a second gate control circuit that is coupled to the memory cell. The memory cell includes a first gate electrode that is formed above a channel region in a semiconductor substrate, a second gate electrode that is formed beside the first gate electrode, and that is capacitively coupled with the first gate electrode through a first insulating layer, and a charge trapping layer that is formed between the channel region and the second gate electrode, and that includes a second insulating layer for trapping a charge. Data stored in a memory cell transistor including the second gate electrode changes depending on an amount of the charge trapped in the charge trapping layer. The first gate control circuit applies a potential to the first gate electrode, when reading the data stored in the memory cell transistor.

Abstract: A ferromagnetic thin-film based digital memory system having memory cells interconnected in a grid that are selected through voltage values supplied coincidently on interconnections made thereto for changing states thereof and determining present states thereof through suitable biasing of grid interconnections.

Abstract: The invention relates to a nonvolatile two-transistor semiconductor memory cell and an associated fabrication method, source and drain regions (2) for a selection transistor (AT) and a memory transistor (ST) being formed in a substrate (1). The memory transistor (ST) has a first insulation layer (3), a charge storage layer (4), a second insulation layer (5) and a memory transistor control layer (6), while the selection transistor (AT) has a first insulation layer (3?) and a selection transistor control layer (4*). By using different materials for the charge storage layer (4) and the selection transistor control layer (4*), it is possible to significantly improve the charge retention properties of the memory cell by adapting the substrate doping with electrical properties remaining the same.

Abstract: A method and/or system and/or apparatus for a dual gate, capacitor less circuit that can act as a state storage device. Further embodiments describe fabrication methods and methods of operation of such a device.

Abstract: A non-volatile memory device includes a memory cell array with a plurality of unit memory cells arranged in a matrix pattern, each of the unit memory cells having first and second non-volatile memory transistors sharing a common source, and a selection transistor connected between the common source and one of the first and second non-volatile memory transistors, a first word line coupled to control gates of the first non-volatile memory transistors arranged in a column direction of the memory cell array, a second word line coupled to control gates of the second non-volatile memory transistors arranged in the column direction of the memory cell array, a selection line coupled to gates of the selected transistors arranged in the column direction of the memory cell array, and at least one bit line coupled to drains of the first and second non-volatile memory transistors.

Abstract: A nonvolatile semiconductor memory device includes: a semiconductor substrate including a first channel, and a source region and a drain region provided on both sides of the first channel; a first insulating film provided on the first channel; a charge retention layer provided on the first insulating film; a second insulating film provided on the charge retention layer; and a semiconductor layer including a second channel provided on the second insulating film, and a source region and a drain region provided on both sides of the second channel.

Abstract: Structures and methods for write once read only memory employing charge trapping in insulators are provided. The write once read only memory cell includes a metal oxide semiconductor field effect transistor having a first source/drain region, a second source/drain region, a channel region between the first and the second source/drain regions, and a gate separated from the channel region by a gate insulator. A plug couples the first source/drain region to an array plate. A bitline is coupled to the second source/drain region. The MOSFET can be programmed by operation in a reverse direction trapping charge in the gate insulator adjacent to the first source/drain region such that the programmed MOSFET operates at reduced drain source current when read in a forward direction.

Abstract: A first channel in the substrate underlying a trap gate is biased to cause trapping of holes or electrons in the trap gate and thereby program the memory device to a programmed state. A second channel in the substrate underlying the trap gate and transverse to the first channel is biased to sense the programmed state. For example, biasing a first channel in the substrate underlying the trap gate to cause trapping of holes or electrons in the trap gate and thereby program the memory device to a programmed state may include applying voltages to a first source/drain region and first gate on a first side of the trap gate and to a second source/drain region and a second gate on a second side of the trap gate, and biasing a second channel in the substrate underlying the trap gate and transverse to the first channel to sense the programmed state may include applying voltages to a third source/drain region on a third side of the trap gate and to a fourth source/drain region on a fourth side of the trap gate.

Abstract: An improved split gate non-volatile memory cell is made in a substantially single crystalline substrate of a first conductivity type, having a first region of a second conductivity type, a second region of the second conductivity type, with a channel region between the first region and the second region in the substrate. The cell has a select gate above a portion of the channel region, a floating gate over another portion of the channel region, a control gate above the floating gate and an erase gate adjacent to the floating gate. The erase gate has an overhang extending over the floating gate. The ratio of the dimension of the overhang to the dimension of the vertical separation between the floating gate and the erase gate is between approximately 1.0 and 2.5, which improves erase efficiency.

Abstract: The present invention relates to an 1-transistor DRAM cell, a DRAM device and a manufacturing method therefor, a driving circuit for a DRAM, a driving method therefore, and a driving method for an 1-transistor DRAM, and a double-gate type 1-transistor DRAM. The present invention comprises a data hold process biasing a word line at a negative voltage level and biasing a sensing line and a bit line at a first constant voltage level; a data purging process resetting data by biasing the word line and the bottom word line at a second constant voltage level and biasing the sensing line and the bit line at the first constant voltage level; and a data write process biasing the word line and the bottom word line at the second constant voltage level and supplying a write data to the bit line.

Abstract: A nonvolatile semiconductor memory device includes: a memory cell array region having memory cells connected in series; a control circuit region disposed below the memory cell array region; and an interconnection portion electrically connecting the control circuit region and the memory cell array region. The memory cell array region includes: a plurality of first memory cell regions having the memory cells; and a plurality of connection regions. The interconnection portion is provided in the connection regions. The first memory cell regions are provided at a first pitch in a first direction orthogonal to a lamination direction of the memory cell array region and the control circuit region. The connection regions are provided between the first memory cell regions mutually adjacent in the first direction, and at a second pitch in a second direction orthogonal to the lamination direction and the first direction.

Abstract: A semiconductor memory device includes: a semiconductor substrate; a stacked body provided on the semiconductor substrate and having a plurality of insulator layers and a plurality of conductive layers alternately stacked; a semiconductor layer provided inside a through-hole formed so as to pass through the stacked body and extending in a stacking direction of the insulator layers and the conductive layers; and a charge trap layer provided between the conductive layer and the semiconductor layer. A lower part in the semiconductor layer is narrower than an upper part therein, and at least the lowermost layer in the conductive layers is thinner than the uppermost layer therein.

Abstract: An operating method of a non-volatile memory adapted for a non-volatile memory disposed on an SOI substrate including a first conductive type silicon body layer is provided. The non-volatile memory includes a gate, a charge storage structure, a second conductive type drain region, and a second conductive type source region. In operating such a non-volatile memory, voltages are applied to the gate, the second conductive type drain region, the second conductive type source region and the first conductive type silicon body layer beneath the gate, to inject electrons or holes in to the charge storage structure or evacuate the electrons from the charge storage structure by a method selected from a group consisting of channel hot carrier injection, source side injection, band-to-band tunnelling hot carrier injection and Fowler-Nordheim (F-N) tunnelling.

Abstract: A semiconductor device is disclosed. The semiconductor device includes a plurality of memory cells that are provided in a matrix and that have a charge storage layer made of an insulating film that is provided on a semiconductor substrate and a plurality of word lines that are provided on the charge storage layer. A plurality of memory cells that are arranged in a single line among the plurality of memory cells arranged in the matrix are coupled to the same word line. The semiconductor device further includes an application section that when reading data from a selected memory cell selected from the plurality of memory cells, applies a voltage to a selected word line to be coupled to the selected memory cell among the plurality of word lines. The application section applies a voltage that has a polarity that is opposite to the voltage applied to the selected word line to non-selected word lines arranged on both adjacent sides of the selected word line.

Abstract: A multi-bit flash memory and a reading method thereof. Multiple reference memory cells for saving reserved data are provided to operate together with multiple data memory cells. Before the data memory cells are read, data stored in the reference memory cell is sensed based on a present reference current. Then, a value of a new reference current for reading the data memory cells is determined according to a difference between the sensed data and the reserved data.

Abstract: Method including selective treatment of storage layer. One embodiment includes the formation of a material layer on a topology with protruding portions, which may be assigned to active areas, and with recessed portions, which may be assigned to isolation structures. A mask material is deposited that grows selectively above the protruding portions and that forms a mask which covers first portions of the material layer wrapping around at least portions of the protruding portions. Openings in the mask are formed above second portions of the material layer above the recessed portions. Then the material layer is treated in the second portions in a self-aligned manner.

Abstract: A semiconductor integrated circuit includes a non-volatile memory built into the semiconductor integrated circuit, the non-volatile memory electrically writing and erasing data and including a memory cell, the memory cell including: a selecting transistor controlled by a word line; an impurity diffused region formed inside a semiconductor substrate, the impurity diffused region being coupled to one of a source and a drain of the selecting transistor; a first electrode formed above the semiconductor substrate with an insulating film therebetween, the first electrode receiving a control signal and part of the first electrode having an opening; a second electrode formed avobe the first electrode so as to oppose the first electrode with an insulating film therebetween, the second electrode having a protrusion which opposes the impurity diffused region with a tunnel film therebetween and projects toward the semiconductor substrate through the opening of the first electrode, and storing information based on an appl

Abstract: A system, method and program product for determining a history state of data in a data retaining device are disclosed. A state of a partially-depleted silicon-on-insulator (PD SOI) device coupled to a data retaining device is measured to indicate a body voltage of the PD SOI device. The body voltage of the PD SOI device may indicate, among others, how long the PD SOI device has been idling, which indirectly indicates how long data in the data retaining device has not been accessed. As such, the current invention may be used efficiently with, e.g., a cache replacement algorithm in a management of the data retaining device.

Abstract: In a nonvolatile memory cell with charge trapping dielectric (150), the tunnel dielectric (140) includes chlorine adjacent to the charge trapping dielectric but no chlorine (or less chlorine) adjacent to the cell's channel region (120). The chlorine adjacent to the charge trapping dielectric serves to improve the programming and/or erase speed. The low chlorine concentration adjacent to the channel region prevents chlorine from degrading the data retention. Other features are also provided.

Abstract: Charge migration in a SONOS memory cell is eliminated by physically separating nitride layer storage sites with dielectric material. Increased storage in a cell is realized with a double gate structure for controlling bit storage in line channels between a source and a drain, such as with a FinFET structure in which the gates are folded over the channels on sides of a fin.

Abstract: A silicon-oxide-nitride-oxide-silicon (SONOS) memory device includes a memory type transistor including a gate with a SONOS structure on a semiconductor substrate. The gate is formed by sequentially stacking a tunneling oxide layer, a memory node structure including a trap site having nano-sized trap elements in which charges passing through the tunneling oxide layer are trapped, and a gate electrode. The nano-sized trap elements may be a crystal layer composed of nanocrystals that are separated from one another to trap the charges. The memory node structure may include additional memory node layers which are isolated from the nano-sized trap elements.

Abstract: The present invention provides a semiconductor device and a method for manufacturing thereof. The semiconductor device includes bit lines disposed in a semiconductor substrate, a first ONO disposed between the bit lines on the semiconductor substrate, and a second ONO film disposed on each of the bit lines. The film thickness of a first silicon nitride film in the first ONO film is larger than the film thickness of a second silicon nitride film in the second ONO film.

Abstract: A semiconductor memory having an electrically writable/erasable memory cell includes a first gate insulating layer made from a compound containing silicon and oxygen; a first charge-storage layer being in contact with the first gate insulating layer made from a silicon nitride film, a silicon oxynitride film, or an alumina film; a second insulating layer thicker than the first gate insulting layer; a second charge-storage layer being in contact with the second insulating layer; a third insulating layer thicker than the first gate insulating layer being in contact with the second charge-storage layer; and a control electrode upon the third insulating layer.

Abstract: A semiconductor processing device according to the invention includes a first non-volatile memory (21) for erasing stored information on a first data length unit, a second non-volatile memory (22) for erasing stored information on a second data length unit, and a central processing unit (2), and capable of inputting/outputting encrypted data from/to an outside. The first non-volatile memory is used for storing an encryption key to be utilized for encrypting the data. The second non-volatile memory is used for storing a program to be processed by the central processing unit. The non-volatile memories to be utilized for storing the program and for storing the encryption key are separated from each other, and the data lengths of the erase units of information to be stored in the non-volatile memories are defined separately.

Abstract: A nonvolatile semiconductor memory device includes a latch circuit including a first inverter and a second inverter cross-coupled to each other, a source node of a MIS transistor of the first inverter and a source node of a MIS transistor of the second inverter being both coupled to a plate line, and a control circuit configured to apply a first potential to the plate line in a store mode to cause a change in threshold voltage to one of the MIS transistors, and configured to apply a second potential to the plate line in a power-on mode to cause the latch circuit to latch data responsive to the change in threshold voltage generated in the store mode, such that the data latched by the latch circuit in the power-on mode is automatically output to outside the nonvolatile semiconductor memory device upon power-on thereof.

Abstract: A storage unit capable of retaining data during sleep mode. The storage unit includes a first latch composed of first and second inverters and a second latch composed of the first inverter and a third inverter, in which the first and second inverters have different threshold voltages. The first inverter comprises an input terminal coupled to a write port and an output coupled to a read port. The second inverter comprises an input terminal coupled to the read port and an output terminal coupled to the write port. The third inverter comprises an input terminal coupled to the write port and an output terminal coupled to the read port.

Abstract: A semiconductor device comprising floating body memory cells performs read and write operations by selectively connecting bit lines and inverted bit lines to sense bit lines and inverted sense bit lines.

Abstract: In a case of writing to a trap type non-volatile memory cell that includes: a laminated insulating film, containing a charge accumulation layer, that is formed on a semiconductor substrate where source, drain and well regions are formed; and a first gate electrode formed on the laminated insulating film, charge injections that are carried on a single memory node multiple times under two or more different writing conditions, the writing condition is a combination of a well voltage applied to the well, a drain voltage applied to the drain and a gate voltage is applied to the first gate. Thereby, it is possible to form a trapezoid-shaped electron distribution in the charge accumulation layer, and thus prevent the charge retention characteristic from deteriorating.