Abstract: The present disclosure provides a semiconductor device with a graphene layer and a method for forming the same. The semiconductor device includes a first source/drain region and a second source/drain region disposed in a semiconductor substrate. The semiconductor device also includes a word line structure disposed in the semiconductor substrate and between the first source/drain region and the second source/drain region. The word line structure includes a gate dielectric layer, and a lower electrode layer disposed over the gate dielectric layer. The word line structure also includes an upper electrode layer disposed over the lower electrode layer, and a first graphene layer disposed between the lower electrode layer and the upper electrode layer.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed herein. An exemplary semiconductor device comprises a semiconductor fin formed on a substrate; and a gate structure disposed over a channel region of the semiconductor fin, the gate structure including a gate dielectric layer and a gate electrode, wherein the gate dielectric layer includes a bottom portion and a side portion, and the gate electrode is separated from the side portion of the gate dielectric layer by a first air gap.

Abstract: This piezoelectric element includes a lower electrode formed on a substrate, a piezoelectric layer formed on the lower electrode, and an upper electrode formed on the piezoelectric layer. The upper electrode includes a first upper electrode layer made of a metal oxide including an amorphous portion at least at a boundary with the piezoelectric layer and a second upper electrode layer formed on the first upper electrode layer.

Abstract: A ferroelectric device structure includes an array of ferroelectric capacitors overlying a substrate, first metal interconnect structures electrically connecting each of first electrodes of the array of ferroelectric capacitors to a first metal pad embedded in a dielectric material layer, and second metal interconnect structures electrically connecting each of the second electrodes of the array of ferroelectric capacitors to a second metal pad embedded in the dielectric material layer. The second metal pad may be vertically spaced from the substrate by a same vertical separation distance as the first metal pad is from the substrate. First metal lines laterally extending along a first horizontal direction may electrically connect the first electrodes to the first metal pad, and second metal lines laterally extending along the first horizontal direction may electrically connect each of the second electrodes to the second metal pad.

Abstract: A method and a composition to stabilize the surface cation chemistry of the perovskite or related oxides, and thus, to minimize or completely avoid the detrimental segregation and phase separation of dopant cations at the surface can include modifying the surface with more oxidizable metal cations and/or more oxidizable metal oxides, thereby reducing the oxygen vacancy concentration at the very surface.

Abstract: The disclosed technology generally relates semiconductor devices, and relates more particularly to a spin transfer torque device, a method of operating the spin-transfer torque device and a method of fabricating the spin-transfer torque device. According to one aspect, a spin-transfer torque device includes a magnetic flux guide layer and a set of magnetic tunnel junction (MTJ) pillars arranged above the magnetic flux guide layer. Each one of the pillars includes a separate free layer, a separate tunnel barrier layer and a separate reference layer. A coupling layer is arranged between the magnetic flux guide layer and the MTJ pillars, wherein a magnetization of the separate free layer of each of the each of the MTJ pillars is coupled, parallel or antiparallel, to a magnetization of the magnetic flux guide layer through the coupling layer.

Abstract: A synapse device includes a perpendicularly magnetized ferrimagnetic racetrack layer, a tunneling barrier layer disposed on the racetrack layer and a reference layer including a perpendicular magnetic alloy. The racetrack layer, the tunneling layer and the reference layer have a channel portion and contact pad portions. First and second contacts are provided over the contact pad portions, and a third contact is provided over the channel portion, wherein the first and second contacts are electrically isolated from the third contact.

Abstract: Provided are an electronic device and a method of manufacturing the same. The electronic device may include a first device provided on a first region of a substrate; and a second device provided on a second region of the substrate, wherein the first device may include a first domain layer including a ferroelectric domain and a first gate electrode on the first domain layer, and the second device may include a second domain layer including a ferroelectric domain and a second gate electrode on the second domain layer. The first domain layer and the second domain layer may have different characteristics from each other at a polarization change according to an electric field. At the polarization change according to the electric field, the first domain layer may have substantially a non-hysteretic behavior characteristic and the second domain layer may have a hysteretic behavior characteristic.

Abstract: A semiconductor device includes a first cell and a second cell. The first cell includes a first circuit, and the first circuit includes a first gate. The second cell is disposed adjacent the first cell and includes a second circuit which includes a second gate. The doping concentration of the first circuit is different from that of the second circuit, and the first gate and the second gate have the same gate critical dimension. A method for manufacturing the semiconductor device is also disclosed herein.

Abstract: Some embodiments include an integrated assembly having bottom electrodes coupled with electrical nodes. Each of the bottom electrodes has a first leg electrically coupled with an associated one of the electrical nodes, and has a second leg joining to the first leg. First gaps are between some of the bottom electrodes, and second gaps are between others of the bottom electrodes. The first gaps alternate with the second gaps. Insulative material and conductive-plate-material are within the first gaps. Scaffold structures are within the second gaps and not within the first gaps. Capacitors include the bottom electrodes, regions of the insulative material and regions of the conductive-plate-material. The capacitors may be ferroelectric capacitors or non-ferroelectric capacitors. Some embodiments include methods of forming integrated assemblies.

Abstract: A magnetic device includes a pinned layer having an in-plane magnetization direction; a free layer, having an in-plane magnetization direction, vertically spaced apart from the pinned layer to be aligned with the pinned layer; a conductive spacer layer disposed between the pinned layer and the free layer; an antiferromagnetic layer disposed to fin the magnetization direction of the pinned layer and vertically spaced apart from the pinned layer to be aligned with the pinned layer; and a noble metal spacer layer disposed between the pinned layer and the antiferromagnetic layer.

Abstract: Controlled IBE techniques for MRAM stack patterning are provided. In one aspect, a method of forming an MRAM device includes: patterning an MRAM stack disposed on a dielectric into individual memory cells using IBE landing on the dielectric while dynamically adjusting an etch time to compensate for variations in a thickness of the MRAM stack, wherein each of the memory cells includes a bottom electrode, an MTJ, and a top electrode; removing foot flares from the bottom electrode of the memory cells which are created during the patterning of the MRAM stack; removing residue from sidewalls of the memory cells which includes metal redeposited during the patterning of the MRAM stack and during the removing of the foot flares; and covering the memory cells in a dielectric encapsulant. An MRAM device is also provided.

Abstract: Provided is a memcapacitor. The memcapacitor includes: a first electrode having a metal-doped perovskite composition; a second electrode disposed on the first electrode; and a dielectric thin film having a perovskite composition, disposed between the first electrode and the second electrode, and having a variable dielectric constant depending on a voltage between the first electrode and the second electrode.

Abstract: A semiconductor device including a 2D material layer disposed between a gate electrode and a substrate and a method of forming the same are disclosed. In an embodiment, a device includes a ferroelectric dielectric layer disposed over and in contact with a semiconductor substrate, the ferroelectric dielectric layer including a 2D material; a gate electrode disposed over the ferroelectric dielectric layer; and source/drain regions disposed on opposite sides of the gate electrode.

Abstract: The energy density of capacitors can be increased by using a material with differential negative capacitance (NC), which was recently observed in FE materials. Described is a more general pathway towards improved electrostatic energy storage densities by engineering the capacitance non-linearity of electrostatic devices. The disadvantages of regular polarizable materials are overcome by using the NC effect, which ideally has no hysteresis losses, leading to a theoretical efficiency of 100%. By storing the energy mostly in an amorphous DE layer, the break-down field strength is much higher compared to pure FE or AFE storage capacitors. In addition, leakage current losses can be reduced by improving the morphology of the insulating materials used.

Abstract: Certain aspects of the present disclosure are directed to a semiconductor device. The semiconductor device generally includes a ferroelectric (FE) semiconductor device having a channel region; a gate oxide; a FE region, wherein the gate oxide is disposed between the FE region and the channel region; a gate region, wherein the FE region is disposed between the gate oxide and the gate region; a first semiconductor region disposed adjacent to the channel region; and a second semiconductor region disposed adjacent to the channel region. The semiconductor device may also include a transistor, wherein a region of the transistor is connected to the gate region, the first semiconductor region, or the second semiconductor region of the FE semiconductor device.

Abstract: Techniques in accordance with embodiments described herein are directed to a MFM structure that includes a resistance component, an inductance component and a capacitance component. The MFM device is equivalent to a series LC circuit with the resistance component coupled in parallel with the capacitance component. The MFM structure is used as a series LC resonant circuit, band-pass circuit, band-stop circuit, low-pass filter, high-pass filter, oscillators, or negative capacitors.

Abstract: The current disclosure is directed to a SRAM bit cell having a reduced coupling capacitance. In a vertical direction, a wordline “WL” and a bitline “BL” of the SRAM cell are stacked further away from one another to reduce the coupling capacitance between the WL and the BL. In an embodiment, the WL is vertically spaced apart from the BL with one or more metallization level that none of the WL or the BL is formed from. Connection island structures or jumper structures are provided to connect the upper one of the WL or the BL to the transistors of the SRAM cell.

Abstract: Various embodiments of the present disclosure are directed towards a memory cell including a first ferromagnetic layer and a second ferromagnetic layer. A bottom electrode via overlies a substrate. A bottom electrode overlies the bottom electrode via. A data storage layer overlies the bottom electrode. The first ferromagnetic layer overlies the data storage layer and has a first magnetization pointing in a first direction. The second ferromagnetic layer overlies the bottom electrode via and has a second magnetization pointing in a second direction orthogonal to the first direct.

Abstract: In a method of manufacturing a negative capacitance structure, a ferroelectric dielectric layer is formed over a first conductive layer disposed over a substrate, and a second conductive layer is formed over the ferroelectric dielectric layer. The ferroelectric dielectric layer includes an amorphous layer and crystals.

Abstract: The present disclosure provides a semiconductor structure, including a substrate having a memory region and a logic region, the memory region including a first group of nanosheets vertically arranged over a first region of the substrate, wherein the first group of nanosheets includes: a first semiconductor nanosheet, a second group of nanosheets vertically arranged over a second region of the substrate adjacent to the first region, wherein the second group of nanosheets includes: a second semiconductor nanosheet, and a third semiconductor nanosheet over the second semiconductor nanosheet, a first metal gate layer surrounding the first semiconductor nanosheet, and a second metal gate layer surrounding the second semiconductor nanosheet, wherein the first metal gate layer is in direct contact with the second metal gate layer.

Abstract: A ferroelectric capacitor comprises two conductive capacitor electrodes having ferroelectric material there-between. At least one of the capacitor electrodes comprise MxSiOy, where “M” is at least one of Ru, Ti, Ta, Co, Pt, Ir. Os, Mo, V, W, Sr, Re, Rh, Pd, La, Zn, In, Sn, and Nb. Other aspects, including method, are disclosed.

Abstract: A capacitor that prevents generation of a substrate capacitance composed of an upper electrode, a substrate, and a lower electrode. Specifically, the capacitor includes a substrate; a lower electrode disposed on the substrate; a dielectric film disposed on the lower electrode; an upper electrode disposed on a part of the dielectric film; and a first terminal electrode that is connected to the upper electrode. Moreover, the upper electrode and the first terminal electrode are formed in a region for forming the lower electrode in a plan view of the capacitor viewed from the first terminal electrode side.

Abstract: A semiconductor device includes a first electrode disposed on a substrate. A capacitor dielectric layer is on the first electrode. A second electrode is on the capacitor dielectric layer. A first insulating layer is on the first and second electrodes and the capacitor dielectric layer. A first interconnection structure is on the first insulating layer and connected to the first electrode. A second interconnection structure is on the first insulating layer and connected to the second electrode. A second insulating layer is on the first and second interconnection structures. A plurality of connection structures are configured to pass through the second insulating layer and be connected to the first and second interconnection structures. Each of the first and second interconnection structures has an aluminum layer.

Abstract: A method of fabricating a symmetric element of a resistive processing unit (RPU) includes forming a substrate with a channel region connecting two doped regions, and forming a source above one of the two doped regions and a drain above the other of the two doped regions. A gate is formed above the channel region, and a bar ferroelectric is disposed above the channel region and below the gate.

Abstract: According to one embodiment, a nonvolatile memory device includes a first wiring extending in a first direction, a second wiring extending in a second direction, a third wiring extending in the second direction and spaced from the second wiring in the first direction. An insulating layer includes a first portion between the second wiring and the third wiring, and a second portion protruding from the first portion in a third direction. A chalcogenide layer is between the first wiring and the second wiring, the first wiring and the third wiring, and also the first wiring and the insulating layer. The chalcogenide layer includes a first layer portion, a second layer portion, and a third layer portion. A concentration of a first element in the third layer portion is higher than that in the first and second layer portions.

Abstract: A semiconductor device includes a semiconductor part; first and second electrodes, the semiconductor part being provided between the first and second electrodes; a control electrode selectively provided between the semiconductor part and the second electrode; and a contacting part electrically connecting the semiconductor part and the second electrode. The semiconductor part includes a first layer of a first conductivity type, a second layer of a second conductivity type provided between the first layer and the second electrode, a third layer of the first conductivity type selectively provided between the second layer and the second electrode, and a fourth layer of the second conductivity type selectively provided between the second layer and the second electrode. The contacting part includes a first semiconductor portion of the first conductivity type contacting the third layer, and a second semiconductor portion of the second conductivity type contacting the fourth layer.

Abstract: The semiconductor device according to the present invention includes a ferroelectric film and an electrode stacked on the ferroelectric film. The electrode has a multilayer structure of an electrode lower layer in contact with the ferroelectric film and an electrode upper layer stacked on the electrode lower layer. The electrode upper layer is made of a conductive material having an etching selection ratio with respect to the materials for the ferroelectric film and the electrode lower layer. The upper surface of the electrode upper layer is planarized.

Abstract: A capacitive element is provided that includes a substrate, a lower electrode on the substrate, first upper electrodes disposed to face the lower electrode, second upper electrodes disposed to face the lower electrode, a dielectric layer disposed between the lower electrode and the first upper electrodes and between the lower electrode and the second upper electrodes, a first wiring conductor that connects the first upper electrodes, and a second wiring conductor that connects the second upper electrodes. The first and second upper electrodes are adjacent to each other in a surface direction along the lower electrode and in an X-axis direction, and the first and second upper electrodes are adjacent to each other in the surface direction along the lower electrode and in a Y-axis direction.

Abstract: A hybrid memory device may include volatile and non-volatile memory cells on a single substrate, or die. The non-volatile memory cells may have ferroelectric capacitors and the volatile memory cells may have paraelectric or linear dielectric capacitors for their respective logic storage components. In some examples, the volatile memory cells may be used as a cache for the non-volatile memory cells. Or the non-volatile memory cells may be used as a back-up for the volatile memory cells. By placing both types of cells on a single die, rather than separate dies, various performance metrics may be improved, including those related to power consumption and operation speed.

Abstract: Structures for a field-effect transistor and methods of forming structures for a field-effect transistor. A gate electrode has a section that is wrapped about a first side surface and a second side surface of a mandrel that is composed of a dielectric material. A channel layer has a channel region that is positioned in part between the first side surface of the mandrel and the section of the gate electrode. The channel layer is composed of a two-dimensional material.

Abstract: A semiconductor memory element is provided including a laminated structure, in which a memory member and a conductor are superposed on a semiconductor substrate. The memory member has a bottom surface in contact with the semiconductor substrate, an upper surface in contact with the conductor, and side surfaces, which are in contact with and surrounded by a partition wall; the bottom surface of the memory member has a width of equal to or not more than 100 nm; a shortest distance between the conductor and the semiconductor substrate is twice or more of the width of the bottom surface of the memory member; the side surface of the memory member has a width, which is either the same as the width of the bottom surface and constant at any position above the bottom surface, or the widest at a position other than the bottom surface and above the bottom surface.

Abstract: The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a gate structure comprising a gate bottom insulating layer inwardly positioned, a gate top insulating layer positioned on the gate bottom insulating layer, a gate top conductive layer positioned on the gate top insulating layer, and a gate filler layer positioned on the gate top conductive layer; and a capacitor structure comprising a capacitor bottom insulating layer inwardly positioned, a capacitor bottom conductive layer positioned on the capacitor bottom insulating layer, a capacitor top insulating layer positioned on the capacitor bottom conductive layer, a capacitor top conductive layer positioned on the capacitor top insulating layer, and a capacitor filler layer positioned on the capacitor top conductive layer. The gate bottom insulating layer is formed of a same material as the capacitor bottom insulating layer.

Abstract: A memory device contains lower electrodes, a buffer layer, a seed layer, a magnetic tunnel junction, a capping layer, synthetic antiferromagnetic layers, and an upper electrode, which are formed on a substrate in a laminated manner. In the memory device, the lower electrodes and the seed layer are formed of a polycrystalline conductive material, and the perpendicular magnetic anisotropy of the magnetic tunnel junction is maintained upon heat treatment at a high temperature of 400° C. or more.

Abstract: Techniques, systems, and devices for time-resolved access of memory cells in a memory array are described herein. During a sense portion of a read operation, a selected memory cell may be charged to a predetermined voltage level. A logic state stored on the selected memory cell may be identified based on a duration between the beginning of the charging and when selected memory cell reaches the predetermined voltage level. In some examples, time-varying signals may be used to indicate the logic state based on the duration of the charging. In some examples, the duration of the charging may be based on a polarization state of the selected memory cell, a dielectric charge state of the selected state, or both a polarization state and a dielectric charge state of the selected memory cell.

Abstract: A ferroelectric field effect transistor includes a semiconductor substrate, with first and second source/drain regions being formed within the semiconductor substrate and being separated by a channel region. An interface layer is disposed on the channel region. A gate insulator layer is disposed on the interface layer. A ferroelectric layer is disposed on the gate insulator layer.

Abstract: According to one embodiment, a multi-layer magnetic nanoparticle includes a core; a first magnetic layer deposited on a surface of the core; a second magnetic layer deposited on a surface of the first magnetic layer, and a third magnetic layer deposited on a surface of the second magnetic layer. The core, the first magnetic layer, the second magnetic layer, and the third magnetic layer comprise different magnetic anisotropies and/or saturation magnetizations with respect to each other.

Abstract: Provided are a two-terminal switching element having a bidirectional switching characteristic, a resistive memory cross-point array including the same, and methods for manufacturing the two-terminal switching element and the cross-point resistive memory array. The two-terminal switching element includes a first electrode and a second electrode. A pair of first conductive metal oxide semiconductor layers electrically connected to the first electrode and the second electrode, respectively, is provided. A second conductive metal oxide semiconductor layer is disposed between the first conductive metal oxide semiconductor layers. Therefore, the two-terminal switching element can show a symmetrical and bidirectional switching characteristic.

Abstract: Disclosed herein is a method of manufacturing an artificial synapse device, which includes forming a first electrode on a substrate, forming a first resistance change layer on the first electrode, and forming an iridium (Ir) electrode on the first resistance change layer. In the case where an artificial synapse device is manufactured by the method of manufacturing an artificial synapse device, it is possible to enhance the reliability of the artificial synapse device by reducing the resistance distribution of the artificial synapse device manufactured by forming oxygen vacancies instead of filaments.

Abstract: The present disclosure provides a semiconductor structure including a substrate, a transistor region having a gate over the substrate, a first doped region, and a second doped region at least partially in the substrate, and a contact plug directly over the gate, a first metal interconnect composed of copper over the transistor region, and a magnetic tunneling junction (MTJ) directly over the contact plug and under the first metal interconnect.

Abstract: A semiconductor device includes a magnetic random access memory (MRAM). The MRAM comprises a plurality of MRAM cells including a first type MRAM cell and a second type MRAM cell. Each of the plurality of MRAM cells includes a magnetic tunneling junction (MTJ) layer including a pinned magnetic layer, a tunneling barrier layer and a free magnetic layer. A size of the MTJ film stack of the first type MRAM cell is different from a size of the MTJ film stack of the second type MRAM cell. In one or more of the foregoing and following embodiments, a width of the MTJ film stack of the first type MRAM cell is different from a width of the MTJ film stack of the second type MRAM cell.

Abstract: A memory cell with dual sidewall spacers and its manufacturing methods are provided. In some embodiments, a multi-layer stack is formed and patterned to form a hard mask, a top electrode and a resistance switching dielectric. Then, a first dielectric spacer layer is formed over the bottom electrode layer, extending alongside the resistance switching dielectric, the top electrode, and the hard mask, and further extending over the hard mask. Then, a second dielectric spacer layer is formed directly on and conformally lining the first dielectric spacer layer. The first dielectric spacer layer is deposited at a first temperature and the second dielectric spacer layer is deposited at a second temperature higher than that of the first temperature.

Abstract: An approach to provide a magnetoresistive random-access memory (MRAM) device that includes a first source/drain contact in a transistor in a semiconductor substrate where the source/drain contact is over a source/drain in the transistor and is surrounded by a first dielectric material. The MRAM device includes a portion of the first source/drain contact connecting to a portion of a bottom electrode of an MRAM device. Furthermore; the MRAM device includes a portion of a top electrode in the MRAM device connecting to a via, wherein the via connects to a M1 metal layer of a semiconductor chip.

Abstract: A nonvolatile memory cell resistance change type nonvolatile memory cell configured to store information by changing an electrical resistance according to application of electrical stress is provided and a nonvolatile memory device including the nonvolatile memory cell is provided. The resistance change type nonvolatile memory cell includes a resistance change material layer including a resistance change material; a ferroelectric layer on a first side of the resistance change material layer, the ferroelectric layer configured to change an electrical resistance of the resistance change material layer according to a polarization direction and polarization size of a ferroelectric therein; a first electrode on the ferroelectric layer and configured to control the polarization direction and the polarization size of the ferroelectric based on an applied voltage; and a second electrode and a third electrode on the resistance change material layer with the first electrode therebetween.

Abstract: An interconnect structure includes a first dielectric layer, an etch stop layer, a conductive via, a conductive line, an intermediate conductive layer, a conductive pillar, and a second dielectric layer. The etch stop layer is over the first dielectric layer. The conductive via is in the first dielectric layer and the etch stop layer. The conductive line is over the conductive via. The intermediate conductive layer is over the conductive line. The conductive pillar is over the intermediate conductive layer. The second dielectric layer surrounds the conductive line, the intermediate conductive layer, and the conductive pillar, and a bottom of the second dielectric layer is lower than a top of the conductive line, and a top of the second dielectric layer is higher than the top of the conductive line.

Abstract: A semiconductor device includes a channel, source/drain structures, and a gate stack. The source/drain structures are on opposite sides of the channel. The gate stack is over the channel, and the gate stack includes a gate dielectric layer, a doped ferroelectric layer, and a gate electrode. The gate dielectric layer is over the channel. The doped ferroelectric layer is over the gate dielectric layer. The gate electrode is over the doped ferroelectric layer. A dopant concentration of the doped ferroelectric layer varies in a direction from the gate electrode toward the channel.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes an isolation structure formed over a substrate, and a first stacked wire structure and a second stacked wire structure extending above the isolation structure. The semiconductor device structure includes a dummy fin structure formed over the isolation structure, and the dummy fin structure is between the first stacked wire structure and the second stacked wire structure. The semiconductor device structure also includes a capping layer formed over the dummy fin structure. The isolation structure has a first width, the dummy fin structure has a second width, and the second width is smaller than the first width.

Abstract: In some embodiments, the present disclosure relates to an integrated circuit. The integrated circuit has a first doped region and a second doped region within a substrate. A FeRAM (ferroelectric random access memory) device is arranged over the substrate between the first doped region and the second doped region. The FeRAM device has a ferroelectric material and a conductive electrode. The ferroelectric material is arranged over the substrate and the conductive electrode is arranged over the ferroelectric material and between sidewalls of the ferroelectric material.

Abstract: Memory field-effect transistors and methods of manufacturing the same are disclosed. An example apparatus includes a semiconductor substrate and a ferroelectric gate insulator of a memory field-effect transistor formed within a trench having walls defined by spacers and a base defined by the semiconductor substrate. The apparatus further includes a gate conductor formed on the ferroelectric gate insulator. The ferroelectric gate insulator is to separate a bottom surface of the gate conductor and the substrate.

Abstract: A display device includes a first touch panel on which a first touch sensing unit including a plurality of coils is disposed, a second touch panel on which a second touch sensing unit including a plurality of sensing nodes coupled to the plurality of coils in a coupling manner with a one-to-one correspondence, and a display panel disposed between the first and second touch panels and displays an image, and the plurality of sensing nodes is formed in a divided structure grouped into first and second node groups based on a touch event detected by the first touch sensing unit.