Abstract: The invention relates to a flash memory cell having a FET transistor with a floating gate on a semiconductor-on-insulator (SOI) substrate composed of a thin film of semiconductor material separated from a base substrate by an insulating buried oxide (BOX) layer, The transistor has in the thin film, a channel, with two control gates, a front control gate located above the floating gate and separated from it by an inter-gate dielectric, and a back control gate located within the base substrate directly under the insulating (BOX) layer and separated from the channel by only the insulating (BOX) layer. The two control gates are designed to be used in combination to perform a cell programming operation. The invention also relates to a memory array made up of a plurality of memory cells according to the first aspect of the invention, which can be in an array of rows and columns, and a method of fabricating such memory cells and memory arrays.

Abstract: A method includes performing a read operation on a memory cell of a device including a sensing line, a bit line coupled to the memory cell, a first transistor having a source-drain path coupled between the sensing line and the bit line, and a second transistor having a gate coupled to sense the sensing line, the performing including providing a gate of the first transistor with a first voltage, providing the sensing line with a second voltage, and providing the bit line with a third voltage, the third voltage being independent from the second voltage.

Abstract: A nonvolatile memory includes a memory cell including a first transistor and a second transistor. The first transistor includes a first channel, a first gate electrode, a first source electrode, and a first drain electrode. The second transistor includes a second channel made of oxide semiconductor material, a second gate electrode, a second source electrode, and a second drain electrode. One of the second source electrode and the second drain electrode is electrically connected to the first gate electrode. Data writing in the memory cell is done by raising the potential of a node between one of the second source electrode and the second drain electrode and the first gate electrode. Data erasure in the memory cell is done by irradiating the second channel with ultraviolet light and lowering the potential of the node.

Abstract: A capacitor-less memory cell, memory device, system and process of forming the capacitor-less memory cell includes forming the memory cell in an active area of a substantially physically isolated portion of the bulk semiconductor substrate. A pass transistor is formed on the active area for coupling with a word line. The capacitor-less memory cell further includes a read/write enable transistor vertically configured along at least one vertical side of the active area and operable during a reading of a logic state with the logic state being stored as charge in a floating body area of the active area, causing different determinable threshold voltages for the pass transistor.

Abstract: Embodiments of the present disclosure provide techniques and configurations for stacking transistors of a memory device. In one embodiment, an apparatus includes a semiconductor substrate, a plurality of fin structures formed on the semiconductor substrate, wherein an individual fin structure of the plurality of fin structures includes a first isolation layer disposed on the semiconductor substrate, a first channel layer disposed on the first isolation layer, a second isolation layer disposed on the first channel layer, and a second channel layer disposed on the second isolation layer, and a gate terminal capacitively coupled with the first channel layer to control flow of electrical current through the first channel layer for a first transistor and capacitively coupled with the second channel layer to control flow of electrical current through the second channel layer for a second transistor. Other embodiments may be described and/or claimed.

Abstract: An electronic device includes a device isolation film formed to define an active region in a substrate, a first gate buried to traverse the active region and the device isolation film in a first direction, and a second gate coupled to the first gate buried in the device isolation film, and extended in a second direction.

Abstract: Provided is a method of operating a semiconductor device, wherein an operating mode is set by adjusting timing of a voltage pulse or by adjusting a voltage level of the voltage pulse.

Abstract: A semiconductor device includes an interlayer insulating film formed on a substrate, a plurality of contacts formed in the interlayer insulating film, and an impurity-doped region formed around the contacts in the interlayer insulating film and along a lengthwise direction of the contacts.

Abstract: A semiconductor device along with circuits including the same and methods of operating the same are described. The device includes an electrically floating body region, and a gate is disposed over a first portion of the body region. The device includes a source region adjoining a second portion of the body region, the second portion adjacent the first portion and separating the source region from the first portion. The device includes a drain region adjoining a third portion of the body region, the third portion adjacent the first portion and separating the drain region from the first portion.

Abstract: Techniques for providing a direct injection semiconductor memory device are disclosed. In one particular exemplary embodiment, the techniques may be realized as a method for biasing a direct injection semiconductor memory device including the steps of applying a first non-negative voltage potential to a first region via a bit line and applying a second non-negative voltage potential to a second region via a source line. The method may also include applying a third voltage potential to a word line, wherein the word line may be spaced apart from and capacitively to a body region that may be electrically floating and disposed between the first region and the second region. The method may further include applying a fourth positive voltage potential to a third region via a carrier injection line, wherein the third region may be disposed below at least one of the first region, the body region, and the second region.

Abstract: A semiconductor device includes: a source line; a bit line; a word line; a memory cell connected to the bit line and the word line; a driver circuit which drives a plurality of second signal lines and a plurality of word lines so as to select the memory cell specified by an address signal; a potential generating circuit which generates a writing potential and a plurality of reading potentials to supply to a writing circuit and a reading circuit; and a control circuit which selects one of a plurality of voltages for correction on a basis of results of the reading circuit comparing a potential of the bit line with the plurality of reading potentials.

Abstract: A register file employing a shared supply structure to improve the minimum supply voltage.

Abstract: Methods, devices, and systems are disclosed for a memory cell having a floating body. A memory cell may include a transistor over an insulation layer, the transistor including a source, and a drain. The memory cell may also include a floating body including a first region positioned between the source and the drain, a second region positioned remote from each of the source and drain, and a passage extending through the insulation layer and coupling the first region to the second region. Additionally, the memory cell may include a bias gate at least partially surrounding the second region and configured for operably coupling to a bias voltage. Furthermore, the memory cell may include a plurality of dielectric layers, wherein each outer vertical surface of the second region has a dielectric layer of the plurality adjacent thereto.

Abstract: A semiconductor device along with circuits including the same and methods of operating the same are described. The device comprises a memory cell including one transistor. The transistor comprises a gate, an electrically floating body region, and a source region and a drain region adjacent the body region. Data stored in memory cells of the device can be refreshed within a single clock cycle.

Abstract: A first capacitor includes a plurality of first conductive layers and second conductive layers. The first conductive layers function as a first electrode of the first capacitor, the second conductive layers function as a second electrode of the first capacitor. The first conductive layers and the second conductive layers are arranged alternately in the direction substantially perpendicular to a semiconductor substrate. A control circuit is configured to control a voltage applied to each of first conductive layers and the second conductive layers according to voltages of gates of a plurality of memory transistors, thereby changing a capacitance of the first capacitor.

Abstract: A semiconductor memory device includes a power supply circuit configured to supply an intermediate voltage between a power supply voltage and a ground voltage to each of a plurality of memory cells. The power supply circuit firsts generates a first intermediate voltage between the power supply voltage and the ground voltage and a second intermediate voltage between the power supply voltage and the ground voltage. In response to a first control signal, the first intermediate voltage is supplied to an output node and the second intermediate voltage stops. A connection control circuit connects the first output node and a second output node when the second intermediate voltage generating circuit stops its operation.

Abstract: An integrated circuit including a link or string of semiconductor memory cells, wherein each memory cell includes a floating body region for storing data. The link or string includes at least one contact configured to electrically connect the memory cells to at least one control line, and the number of contacts in the string or link is the same as or less than the number of memory cells in the string or link.

Abstract: A non-volatile semiconductor memory device includes: a charge accumulation layer (CAL) on a substrate; a memory gate formed onto the substrate through the CAL; a first side gate formed through a first insulating film on a first side of the memory gate; a second side gate formed through a second insulating film on a second side opposite to the first side; a first impurity implantation region (IIR1) in the substrate adjacent the first side gate; a second impurity implantation region (IIR2) formed in the substrate on a side of the second side gate; and a channel region between IIR1 and IIR2. The channel region includes a first region corresponding to a boundary between the CAL and the substrate; a select side region between the first region and IIR1; and an assist side region between the first region and IIR2. The select side region is longer than the assist side region.

Abstract: A nonvolatile semiconductor memory device includes an MIS transistor having nodes, a control circuit configured to apply a first set of potentials to the nodes to cause an irreversible change in transistor characteristics, to apply a second set of potentials to the nodes to cause a first current to flow through the MIS transistor in a first direction, and to apply the second set of potentials to the nodes to cause a second current to flow through the MIS transistor in a second direction opposite the first direction, and a sense circuit configured to produce a signal responsive to a difference between the first current and the second current.

Abstract: A memory device includes first and second inverters cross-coupled between first and second nodes. The first inverter is configured to be supplied by a first supply voltage via a first transistor and the second inverter is configured to be supplied by the first supply voltage via a second transistor. A first control circuit is configured to control a gate node of the first transistor based on the voltage at the second node and at a gate node of the second transistor. A second control circuit is configured to control the gate node of the second transistor based on the voltage at the first node and at the gate node of the first transistor.

Abstract: A vertical capacitor-less DRAM cell is described, including: a source layer having a first conductivity type, a storage layer disposed on the source layer and having a second conductivity type, an active layer disposed on the storage layer and having the first conductivity type, a drain layer disposed on the active layer and having the second conductivity type, an address gate disposed beside the active layer and separated from the same by a first gate dielectric layer, and a storage gate disposed beside the storage layer and separated from the same by a second gate dielectric layer. The DRAM cell can be written by turning on the MOSFET formed by the storage layer, the active layer, the drain layer, the first gate dielectric layer and the address gate to inject carriers into the storage layer from the active layer.

Abstract: There is a method for enabling a SONOS transistor to be used as both a switch and a memory. FN tunneling is carried out through the source or drain of the transistor, so as to further change the state of electrons stored in an upper charge storage layer adjacent to the drain or source, and the variation in gate-induced drain leakage is used to recognize the memory state of the drain and source. A stable threshold voltage of the transistor is always maintained during this operation. The present invention enables one single transistor having dual features of switch and memory, while being provided with a two-bit memory effect, thus providing a higher memory density in comparison with a general transistor.

Abstract: A semiconductor device, including: a first semiconductor layer including first transistors, wherein the first transistors are interconnected by at least one metal layer including aluminum or copper; and a second mono-crystallized semiconductor layer including second transistors and overlaying the at least one metal layer, wherein the at least one metal layer is in-between the first semiconductor layer and the second mono-crystallized semiconductor layer, wherein the second mono-crystallized semiconductor layer is less than 100 nm in thickness, and wherein the second transistors include horizontally oriented transistors.

Abstract: An Integrated device comprising a first monocrystalline layer comprising logic circuit regions and a second monocrystalline layer comprising memory regions constructed above first monocrystalline layer, wherein the memory regions comprise second transistors, wherein said second transistors comprise drain and source that are horizontally oriented with respect to the second monocrystalline layer, and a multiplicity of vias through the second monocrystalline layer providing connections between the memory regions and the logic circuit regions, wherein at least one of the multiplicity of vias have a radius of less than 100 nm.

Abstract: According to one embodiment, a semiconductor memory device includes memory cells, a memory cell array, a word line, a bit line, a source line, a row decoder, a sense amplifier, and a first MOS transistor. The word line is connected to gates of the memory cells. The bit line is electrically connected to drains of the memory cells. The source line is electrically connected to sources of the memory cells. The row decoder selects the word line. The sense amplifier senses and amplifies data read onto the bit line in a read operation. The first MOS transistor is capable of connecting a well region where the memory cells are formed with the source line and is arranged between the row decoder or the sense amplifier and the memory cell array.

Abstract: A semiconductor device includes a first transistor, formed in a substrate, that includes a first gate insulating film, a source and a drain region, a first gate electrode, and a first sidewall, and a second transistor that includes a second gate insulating film, a second gate electrode, a source and a drain region, and a second sidewall. The first transistor includes a portion of a logic circuit. The second transistor includes a transistor included in a memory cell of a DRAM, or includes a portion of a peripheral circuit that performs writing and erasing with respect to the DRAM. The first gate insulating film has a same thickness as that of the second gate insulating film. The first gate electrode has the same thickness as that of the second gate electrode. A layer structure of the first sidewall is a same as a layer structure of the second sidewall.

Abstract: A memory includes a first tunneling field effect transistor including a first drain and a first source, the first drain coupled to a first resistive memory element. The memory includes a second tunneling field effect transistor including a second drain and sharing the first source, the second drain coupled to a second resistive memory element. The memory includes a first region coupled to the first source for providing a source node.

Abstract: Multi-gate metal-oxide-semiconductor (MOS) transistors and methods of operating such multi-gate MOS transistors are disclosed. In one embodiment, the multi-gate MOS transistor comprises a first gate associated with a first body factor and comprising a first gate electrode for applying a first gate voltage, and a second gate associated with a second body factor greater than or equal to the first body factor and comprising a second gate electrode for applying a second gate voltage. The multi-gate MOS transistor further comprises a body of semiconductor material between the first dielectric layer and the second dielectric layer, where the semiconductor body comprises a first channel region located close to the first dielectric layer and a second channel region located close to the second dielectric layer. The multi-gate MOS transistor still further comprises a source region and a drain region each having a conductivity type different from a conductivity type of the body.

Abstract: A semiconductor device includes a sub word line driver. A first sub word line and a second sub word line transmit an operation signal to a memory cell. A main word line optionally sends the operation signal to the first sub word line and the second sub word line. A switching transistor is disposed between the first sub word line and the second sub word line. A gate of the switching transistor is connected the main word line.

Abstract: It is an object to solve inhibition of miniaturization of an element and complexity of a manufacturing process thereof. It is another object to provide a nonvolatile memory device and a semiconductor device having the memory device, in which data can be additionally written at a time besides the manufacturing time and in which forgery caused by rewriting of data can be prevented. It is further another object to provide an inexpensive nonvolatile memory device and semiconductor device. A memory element is manufactured in which a first conductive layer, a second conductive layer that is beside the first conductive layer, and conductive fine particles of each surface which is covered with an organic film are deposited over an insulating film. The conductive fine particles are deposited between the first conductive layer and the second conductive layer.

Abstract: Methods for fabricating integrated circuits include fabricating a logic device on a substrate, forming an intermediate semiconductor substrate on a surface of the logic device, and fabricating a capacitor-less memory cell on the intermediate semiconductor substrate. Integrated circuits with capacitor-less memory cells formed on a surface of a logic device are also disclosed, as are multi-core microprocessors including such integrated circuits.

Abstract: In a sense circuit for DRAM memory cell a switch is provided between the bit line BL and local bit line LBL connected to the memory cells for isolation and coupling of these bit lines. The bit line BL is precharged to the voltage of VDL/2, while the local bit line LBL is precharged to the voltage of VDL. VDL is the maximum amplitude voltage of the bit line BL. A sense amplifier SA comprises a first circuit including a differential MOS pair having the gate connected to the bit line BL and a second circuit connected to the local bit line LBL for full amplitude amplification and for holding the data. When the bit line BL and local bit line LBL are capacitance-coupled via a capacitor, it is recommended to use a latch type sense amplifier SA connected to the local bit line LBL.

Abstract: A semiconductor device comprises a transistor comprising a gate, a source, a drain, and a gate insulating layer, and an auxiliary line formed over the drain and electrically insulated from the drain. During a turn-off operation of the transistor, voltage to increase a resistance of the drain is supplied to the auxiliary line.

Abstract: A memory device according to the invention can be operated with a single potential, by which the use of a voltage converter can be excluded, leading to the reduction of power consumption. Such an operation can be achieved by utilizing capacitive coupling of a capacitor connected to a gate of a transistor for data writing. That is, the capacitive coupling is induced by inputting a signal, which is supplied by a delay circuit configured to delay a write signal having a potential equal to the power supply potential, to the capacitor. Increase in the potential of the gate by the capacitive coupling allows the transistor to be turned on in association with the power supply potential applied to the gate from a power supply. Data is written by inputting a signal having a potential equal to the power supply potential or a grounded potential to a node through the transistor.

Abstract: Noise generated on a word line is reduced without increasing a load on the word line. A semiconductor device is provided in which a plurality of storage elements each including at least one switching element are provided in matrix; each of the plurality of storage elements is electrically connected to a word line and a bit line; the word line is connected to a gate (or a source and a drain) of a transistor in which minority carriers do not exist substantially; and capacitance of the transistor in which minority carriers do not exist substantially can be controlled by controlling a potential of a source and a drain (or a gate) the transistor in which minority carriers do not exist substantially. The transistor in which minority carriers do not exist substantially may include a wide band gap semiconductor.

Abstract: There is provided a technology which can allow a semiconductor chip formed with a nonvolatile memory to be sufficiently reduced in size. There is also provided a technology which can ensure the reliability of the nonvolatile memory. In a memory cell of the present invention, a boost gate electrode is formed over a control gate electrode via an insulating film. The boost gate electrode has the function of boosting a voltage applied to a memory gate electrode through capacitive coupling between the boost gate electrode and the memory gate electrode. That is, during a write operation or an erase operation to the memory cell, a high voltage is applied to the memory gate electrode and, to apply the high voltage to the memory gate electrode, the capacitive coupling using the boost gate electrode is subsidiarily used in the present invention.

Abstract: A semiconductor memory device includes: a memory cell array provided with a plurality of memory cells in a matrix; and a power supply circuit configured to supply an intermediate voltage between a power supply voltage and a ground voltage to each of the plurality of memory cells.

Abstract: A memory circuit includes a transistor having a channel in an oxide semiconductor layer, a capacitor, a first arithmetic circuit, a second arithmetic circuit, a third arithmetic circuit, and a switch. An output terminal of the first arithmetic circuit is electrically connected to an input terminal of the second arithmetic circuit. The input terminal of the second arithmetic circuit is electrically connected to an output terminal of the third arithmetic circuit via the switch. An output terminal of the second arithmetic circuit is electrically connected to an input terminal of the first arithmetic circuit. An input terminal of the first arithmetic circuit is electrically connected to one of a source and a drain of the transistor. The other of the source and the drain of the transistor is electrically connected to one of a pair of electrodes of the capacitor and to an input terminal of the third arithmetic circuit.

Abstract: In accordance with an aspect of the present disclosure, a memory cell (1) or select element is provided. The element includes an ion conductor element (3) formed of a ion conductor material with mobile metal ions, a first electrically conducing electrode (4) in electrical contact with the ion conductor element, and a second electrically conducting electrode (6) in electrical contact with the ion conductor element, so that the memory cell or select element is programmable by applying an electrical voltage between the first electrode and the second electrode that causes the metal ions to be influenced so that an electrical resistance across the ion conductor element is caused to vary, for example because a metallic protrusion (7) is caused to grow or decompose. In contrast to prior art approaches, the ion conductor element has a shape that is asymmetrical with respect to an exchange of the first electrode (4) and the second electrode (6) for each other.

Abstract: In a semiconductor memory device in which each memory cell is constituted by one transistor, in a memory cell pattern, two adjacent bits form one diffusion pattern, two adjacent transistors share a source region, and two drain regions are separated from each other. A plurality of arrays in each of which at least a column of the diffusion patterns is disposed include bit lines, and the bit lines of the first array are independent of the bit lines of the second array. In an interface between the arrays, ends at one side of the bit lines of each of the arrays are located on an associated one of two drain regions which are separated from each other with the source region which is shared on one diffusion pattern sandwiched therebetween. This configuration can provide a sufficient bit-line separation width, and reduce the area.

Abstract: When performing a data erase operation, the control circuit generates positive holes at least at any one of the drain side select transistor and the source side select transistor, and supply the positive holes to a body of the memory string to raise a voltage of the body of the memory string to a first voltage. Then, it applies a voltage smaller than the first voltage to a first word line among the plurality of the word lines during a first time period. In addition, it applies a voltage smaller than the first voltage to a second word line different from the first word line during a second time period. The second time period is different from the first time period.

Abstract: A selection operation is performed for individual memory cells. A device includes a first memory cell and a second memory cell provided in the same row as the first memory cell, each of which includes a field-effect transistor having a first gate and a second gate. The field-effect transistor controls at least data writing and data holding in the memory cell by being turned on or off. The device further includes a row selection line electrically connected to the first gates of the field-effect transistors included in the first memory cell and the second memory cell, a first column selection line electrically connected to the second gate of the field-effect transistor included in the first memory cell, and a second column selection line electrically connected to the second gate of the field-effect transistor included in the second memory cell.

Abstract: A semiconductor device along with circuits including the same and methods of operating the same are described. The device includes an electrically floating body region, and a gate is disposed over a first portion of the body region. The device includes a source region adjoining a second portion of the body region, the second portion adjacent the first portion and separating the source region from the first portion. The device includes a drain region adjoining a third portion of the body region, the third portion adjacent the first portion and separating the drain region from the first portion.

Abstract: A semiconductor storage device according to an embodiment includes wells in a semiconductor substrate, fins formed on the wells, gate electrodes provided on one side and another opposite side of each fin via a gate insulating film to form a channel region in the fin, impurity-diffused layers that each form a potential barrier that confines holes in a body region within the channel region, and source/drain layers each formed at the fin such that the channel region is sandwiched between the source layer and the drain layer. At the time of writing of data ‘1’, a gate voltage is set to a negative potential, a well bias voltage is set to a positive potential, and a drain voltage is set to a positive potential.

Abstract: The semiconductor memory device includes an initialization memory cell having a first inverter circuit including a first transistor and a second transistor, and a second inverter circuit whose input portion is connected to an output portion of the first inverter circuit and output portion is connected to an input portion of the first inverter circuit, and including a third transistor and a fourth transistor. An absolute value of a threshold voltage of the third transistor is smaller than that of the first transistor.

Abstract: A nonvolatile semiconductor memory device includes an MIS transistor having nodes, a control circuit configured to apply a first set of potentials to the nodes to cause an irreversible change in transistor characteristics, to apply a second set of potentials to the nodes to cause a first current to flow through the MIS transistor in a first direction, and to apply the second set of potentials to the nodes to cause a second current to flow through the MIS transistor in a second direction opposite the first direction, and a sense circuit configured to produce a signal responsive to a difference between the first current and the second current.

Abstract: A first field-effect transistor provided over a substrate in which an insulating region is provided over a first semiconductor region and a second semiconductor region is provided over the insulating region; an insulating layer provided over the substrate; a second field-effect transistor that is provided one flat surface of the insulating layer and includes an oxide semiconductor layer; and a control terminal are provided. The control terminal is formed in the same step as a source and a drain of the second field-effect transistor, and a voltage for controlling a threshold voltage of the first field-effect transistor is supplied to the control terminal.

Abstract: A storage element capable of retaining data even after supply of power supply voltage is stopped is provided. In the storage element retaining data in synchronization with a clock signal, with the use of a capacitor and a transistor having a channel in an oxide semiconductor layer, the data can be retained even after supply of power supply voltage is stopped. Here, when the transistor is turned off while the level of the clock signal is kept constant before the supply of power supply voltage is stopped, the data can be retained accurately in the capacitor. By applying such a storage element to each of a CPU, a memory, and a peripheral control device, supply of power supply voltage can be stopped in the entire system, so that the power consumption of the entire system can be reduced.

Abstract: Methods, devices, and systems are disclosed relating to a memory cell having a floating body. A memory cell includes a transistor comprising a drain and a source each formed in silicon and a gate positioned between the drain and the source. The memory cell may further include a bias gate recessed into the silicon and positioned between an isolation region and the transistor. In addition, the bias gate may be configured to be operably coupled to a bias voltage. The memory cell may also include a floating body within the silicon. The floating body may include a first portion adjacent the source and the drain and vertically offset from the bias gate and a second portion coupled to the first portion. Moreover, the bias gate may be formed adjacent to the second portion.

Abstract: A non-volatile semiconductor memory cell with dual functions includes a substrate, a first gate, a second gate, a third gate, a charge storage layer, a first diffusion region, a second diffusion region, and a third diffusion region. The second gate and the third gate are used for receiving a first voltage corresponding to a one-time programming function of the dual function and a second voltage corresponding to a multi-time programming function of the dual function. The first diffusion region is used for receiving a third voltage corresponding to the one-time programming function and a fourth voltage corresponding to the multi-time programming function. The second diffusion region is used for receiving a fifth voltage corresponding to the multi-time programming function.