Abstract: The present disclosure relates to semiconductor structures and, more particularly, to a multi-level ferroelectric memory cell and methods of manufacture. The structure includes: a first metallization feature; a tapered ferroelectric capacitor comprising a first electrode, a second electrode and ferroelectric material between the first electrode and the second electrode, the first electrode contacting the first metallization feature; and a second metallization feature contacting the second electrode.

Abstract: A semiconductor device including a decoupling capacitor disposed between adjacent device source-drain regions, the decoupling capacitor comprising an outer metal liner, a dielectric disposed adjacent to the outer metal liner, and an inner metal liner disposed adjacent to the dielectric, a single diffusion break isolation region disposed between the adjacent device source-drain regions. The outer metal liner is disposed in electrical contact with the adjacent device source-drain regions.

Abstract: The present disclosure provides a method for manufacturing semiconductor element. The method includes: a first masking process, forming a resist layer on the surface of the substrate; a channel forming process, implanting impurities with the same polarity as a well of an FET region into the surface of the substrate, and forming a channel region for the well of the FET region; a gate forming process, forming gates G respectively on the well of the FET region and the well of the variable-capacitance diode region separated by insulating films; a second masking process, generating a second implantation barrier layer on the surface of the substrate; and an epitaxy forming process, implanting impurities with the opposite polarity to that of the well of the FET region into the surface of the substrate, and forming an epitaxy region for the well of the FET region.

Abstract: Embodiments of a deep trench capacitor are disclosed. In one example a plurality of deep trenches is located in a first region of a semiconductor wafer, the first region having a first conductivity type. A corresponding dielectric layer is located on a surface of each of the plurality of deep trenches, and a corresponding doped polysilicon filler is located within each of the dielectric layers. Dielectric-filled trenches are located between each of the dielectric layers and the surface of the semiconductor wafer.

Abstract: A testing system for carrying out electrical testing of at least one first through via forms an insulated via structure extending only part way through a substrate of a first body of semiconductor material. The testing system has a first electrical test circuit integrated in the first body and electrically coupled to the insulated via structure. The first electrical test circuit enables detection of at least one electrical parameter of the insulated via structure.

Abstract: A semiconductor device and a method for fabricating the same are provided. A semiconductor device having a substrate can include a lower semiconductor layer, an upper semiconductor layer on the lower semiconductor layer, and a buried insulating layer between the lower semiconductor layer and the upper semiconductor layer. A first trench can be in the upper semiconductor layer having a lowest surface above the buried insulating layer and a first conductive pattern recessed in the first trench. A second trench can be in the lower semiconductor layer, the buried insulating layer, and the upper semiconductor layer. A second conductive pattern can be in the second trench and a first source/drain region can be in the upper semiconductor layer between the first conductive pattern and the second conductive pattern.

Abstract: A trench DMOS transistor with a very low on-state drain-to-source resistance and a high gate-to-drain charge includes one or more floating islands that lie between the gate and drain to reduce the charge coupling between the gate and drain, and effectively lower the gate-to-drain capacitance.

Abstract: The present disclosure relates to a method of forming a deep trench capacitor. In some embodiments, the method may be performed by selectively etching a substrate to form a trench having serrated sidewalls defining a plurality of curved depressions. A dielectric material is formed within the trench. The dielectric material conformally lines the serrated sidewalls. A conductive material is deposited within the trench and is separated from the substrate by the dielectric material. The dielectric material is configured to act as a capacitor dielectric between a first electrode comprising the conductive material and a second electrode arranged within the substrate.

Abstract: A method for a photolithographic fabricating process to define pillars having small pitch and pillar size. The method includes coating a hard mask layer of a wafer with a photoresist. The wafer is exposed with a first line pattern comprising a plurality of parallel lines in a first direction. The wafer is then exposed with a second line pattern comprising a plurality of parallel lines in a second direction orthogonal to the first direction. The wafer is then developed to remove areas of the photoresist that were exposed by the first line pattern and the second line pattern resulting in a plurality of pillars.

Abstract: An imaging system includes a light source that, in operation, emits an emitted light containing a near-infrared light in a first wavelength region, an image sensor, and a double-band pass filter that transmits a visible light in at least a part of a wavelength region out of a visible region and the near-infrared light in the first wavelength region. The image sensor includes light detection cells, a first filter that selectively transmits the near-infrared light in the first wavelength region, second to fourth filters that selectively transmit lights in second to fourth wavelength regions, respectively, which are contained in the visible light, and an infrared absorption filter. The infrared absorption filter faces the second to fourth filters and absorbs the near-infrared light in the first wavelength region.

Abstract: A semiconductor device and methods for making the same are disclosed. The device may include: a first transistor structure; a second transistor structure; a capacitor structure comprising a trench in the substrate between the first and second transistor structures, the capacitor structure further comprising a doped layer over the substrate, a dielectric layer over the doped layer, and a conductive fill material over the dielectric layer; a first conductive contact from the first transistor structure to a first bit line; a second conductive contact from the second transistor to a non-volatile memory element; and a third conductive contact from the non-volatile memory element to a second bit line.

Abstract: A method for forming a contact plug layout include following steps. (a) Receiving a plurality of active region patterns and a plurality of buried gate patterns that are parallel with each other, and each active region pattern overlaps two buried gate patterns to form two overlapping regions and one contact plug region in between the two overlapping regions in each active region pattern; and (b) forming a contact plug pattern in each contact plug region, the contact plug pattern respectively includes a parallelogram, and an included angle of the parallelogram is not equal to 90°. The contact plug pattern in each active region pattern partially overlaps the two buried gate pattern, respectively. The step (a) to the step (b) are implemented using a computer.

Abstract: A semiconductor device that can evacuate the information in a DRAM automatically at the time of power supply cutoff is provided. A memory cell includes a DRAM cell that holds information at a storage node, a nonvolatile memory cell, and a transistor. The nonvolatile memory cell holds information by use of the first threshold voltage as an erase state and the second threshold voltage as a write state, and shifts to the write state by a write voltage being applied in the erase state. The transistor selects whether or not to apply the write voltage (voltage of a write voltage line) to the nonvolatile memory cell according to the voltage level at the storage node of the DRAM cell.

Abstract: A method for manufacturing an electronic device and an electronic device are disclosed. In an embodiment the method comprises forming an opening in an isolation layer, isotropically etching the opening thereby forming an extended opening with curved sidewalls, and forming a conductive material in the opening.

Abstract: A semiconductor memory device includes a bit line; two or more word lines; and a memory cell including two or more sub memory cells that each include a transistor and a capacitor. One of a source and a drain of the transistor is connected to the bit line, the other of the source and the drain of the transistor is connected to the capacitor, a gate of the transistor is connected to one of the word lines, and each of the sub memory cells has a different capacitance of the capacitor.

Abstract: The inventive concepts provide semiconductor devices and methods of manufacturing the same. Semiconductor devices of the inventive concepts may include a fin region comprising a first fin subregion and a second fin subregion separated and isolated from each other by an isolation insulating layer disposed therebetween, a first gate intersecting the first fin subregion, a second gate intersecting the second fin subregion, and a third gate intersecting the isolation insulating layer.

Abstract: An image sensor includes a semiconductor material with a photodiode disposed in the semiconductor material, and a transfer gate disposed adjacent to an edge of the photodiode. A dielectric layer is also disposed between the semiconductor material and the transfer gate. A hard mask is disposed in an encapsulation layer and lateral bounds of the hard mask are coextensive with lateral bounds of the transfer gate. A first contact trench extends through the encapsulation layer and through the dielectric layer and contacts the semiconductor material. A second contact trench extends through the encapsulation layer and through the hard mask and contacts the transfer gate.

Abstract: The present disclosure relates to a split gate memory device which requires less number of processing steps than traditional baseline processes and methods of making the same. Word gate/select gate (SG) pairs are formed around a sacrificial spacer. The resulting SG structure has a distinguishable non-planar top surface. The spacer layer that covers the select gate also follows the shape of the SG top surface. A dielectric disposed above the inter-gate dielectric layer and arranged between the neighboring sidewalls of the each memory gate and select gate provides isolation between them.

Abstract: Aspects of the present disclosure describe a high density trench-based power. The active devices may have a two-step gate oxide. A lower portion may have a thickness that is larger than the thickness of an upper portion of the gate oxide. A lightly doped sub-body layer may be formed below a body region between two or more adjacent active device structures of the plurality. The sub-body layer extends from a depth of the upper portion of the gate oxide to a depth of the lower portion of the gate oxide It is emphasized that this abstract is provided to comply with rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: In a method of forming a split gate memory cell, a sacrificial spacer is formed over a semiconductor substrate. A first layer of conductive material is formed over a top surface and sidewalls of the sacrificial spacer. A first etch back process is formed on the first layer of conductive material to expose the top surface of the sacrificial spacer and upper sidewall regions of the sacrificial spacer. A conformal silicide-blocking layer is then formed which extends over the etched back first layer of conductive material and over the top surface of the sacrificial spacer.

Abstract: Systems and methods of forming semiconductor devices. A trench capacitor comprising deep trenches is formed in an n+ type substrate. The deep trenches have a lower portion partially filled with a trench conductor surrounded by a storage dielectric. A polysilicon growth is formed in an upper portion of the deep trenches. The semiconductor device includes a single-crystal semiconductor having an angled seam separating a portion of the polysilicon growth from an exposed edge of the deep trenches. A word-line is wrapped around the single-crystal semiconductor. A bit-line overlays the single-crystal semiconductor.

Abstract: After the formation of a first interlayer insulating, an etching stopper film made of SiON is formed thereon. Subsequently, a contact hole extending from the upper surface of the etching stopper film and reaching a high concentration impurity region is formed, and a first plug is formed by filling W into the contact hole. Next, a ferroelectric capacitor, a second interlayer insulating film, and the like are formed. Thereafter, a contact hole extending from the upper surface of the interlayer insulating film and reaching the first plug is formed. Then, the contact hole is filled with W to form a second plug. With this, even when misalignment occurs, the interlayer insulating film is prevented from being etched.

Abstract: The present disclosure describes a method of fabricating semiconductor device including providing a semiconductor substrate and a gate stack disposed on the semiconductor substrate. A first spacer element is formed on the substrate abutting the first gate stack. In an embodiment, a source/drain region is then formed. A second spacer element is then formed is adjacent the first spacer element. The second spacer element has a second height from the surface of the substrate, and the first height is greater than the second height. In embodiments, the second spacer element is used as an etch stop in forming a contact to the source/drain region.

Abstract: After formation of semiconductor fins in an upper portion of a bulk semiconductor substrate, a shallow trench isolation layer is formed, which includes a dielectric material and laterally surround lower portions of each semiconductor fin. Trenches are formed between lengthwise sidewalls of neighboring pairs of semiconductor fins. Portions of the shallow trench isolation layer laterally surrounding each trench provide electrical isolation between the buried plate and access transistors. A strap structure can be formed by etching a via cavity overlying a portion of each trench and a source region of the corresponding access transistor, and filling the via cavity with a conductive material. A trench top oxide structure electrically isolates an inner electrode of each trench capacitor from an overlying gate line for the access fin field effect transistor.

Abstract: A semiconductor nanowire is formed integrally with a wraparound semiconductor portion that contacts sidewalls of a conductive cap structure located at an upper portion of a deep trench and contacting an inner electrode of a deep trench capacitor. The semiconductor nanowire is suspended from above a buried insulator layer. A gate dielectric layer is formed on the surfaces of the patterned semiconductor material structure including the semiconductor nanowire and the wraparound semiconductor portion. A wraparound gate electrode portion is formed around a center portion of the semiconductor nanowire and gate spacers are formed. Physically exposed portions of the patterned semiconductor material structure are removed, and selective epitaxy and metallization are performed to connect a source-side end of the semiconductor nanowire to the conductive cap structure.

Abstract: One illustrative integrated circuit product disclosed herein includes a metal-1 metallization layer positioned above a semiconducting substrate, a capacitor positioned between a surface of the substrate and a bottom of the metal-1 metallization layer, wherein the capacitor includes a plurality of conductive plates that are oriented in a direction that is substantially normal relative to the surface of the substrate, and at least one region of insulating material positioned between the plurality of conductive plates.

Abstract: A method for forming a memory cell transistor is disclosed which includes providing a substrate, forming a trench structure in the substrate, depositing a conductive substance on the surface of the substrate to form a conductive member inside the trench structure, forming one or more dielectric layers on the surface of the substrate, forming one or more first conductive layers on top of the dielectric layers, and etching the first conductive layers and the dielectric layers to form a hole structure extending through the first conductive and the dielectric layers, reaching to the substrate surface. The formed memory cell transistor thus comprises a hole structure which is formed from the surface of the top first conductive layer, extending downwards through the first conductive layers and the dielectric layers, and reaching the substrate surface. One or more second conductive layers may be formed on top of the first conductive layers, with the second conductive layer material filling the hole structure.

Abstract: An improved field effect transistors (FETs) and methods of manufacturing the field effect transistors (FETs) are provided. The method of manufacturing a zero capacitance random access memory cell (ZRAM) includes comprises forming a finFET on a substrate and enhancing a storage capacitance of the finFET. The enhancement can be by either adding a storage capacity to the finFET or altering a portion of the finFET after formation of a fin body of the finFET.

Abstract: This semiconductor device according to the present invention includes a plurality of cylindrical lower electrodes aligned densely in a memory array region; a plate-like support which is contacted on the side surface of the cylindrical lower electrodes, and links to support the plurality of the cylindrical lower electrodes; a pore portion provided in the plate-like support; a dielectric film covering the entire surface of the cylindrical lower electrodes and the plate-like support in which the pore portion is formed; and an upper electrode formed on the surface of the dielectric film, wherein the boundary length of the part on the side surface of the cylindrical lower electrode which is exposed on the pore portion is shorter than the boundary length of the part on the side surface of the cylindrical lower electrode which is not exposed on the pore portion.

Abstract: Methods of fabricating a semiconductor device are provided. The method includes forming a first mold layer on a in a cell region and a peripheral region, forming first storage nodes penetrating the first mold layer in the cell region and a first contact penetrating the first mold layer in the peripheral region, forming a second mold layer on the first mold layer, forming second storage nodes that penetrate the second mold layer to be connected to respective ones of the first storage nodes, removing the second mold layer in the cell and peripheral regions and the first mold layer in the cell region to leave the first mold layer in the peripheral region, and forming a second contact that penetrates a first interlayer insulation layer to be connected to the first contact. Related devices are also provided.

Abstract: A semiconductor device comprises: a semiconductor substrate including an active region defined as a device isolation film; a bit line hole disposed over the top portion of the semiconductor substrate; an oxide film disposed at sidewalls of the bit line hole; and a bit line conductive layer buried in the bit line hole including the oxide film. A bit line spacer is formed with an oxide film, thereby reducing a parasitic capacitance. A storage node contact is formed to have a line type, thereby securing a patterning margin. A storage node contact plug is formed with polysilicon having a different concentration, thereby reducing leakage current.

Abstract: A dynamic random access memory (DRAM) device has a metal-insulator-metal (MIM) capacitor electrically connected to a PN junction diode through a metal bridge for protecting the MIM capacitor from charge damage generated in back end of line (BEOL) plasma process.

Abstract: A finFET trench circuit is disclosed. FinFETs are integrated with trench capacitors by employing a trench top oxide over a portion of the trench conductor. A passing gate is then disposed over the trench top oxide to form a larger circuit, such as a DRAM array. The trench top oxide is formed by utilizing different growth rates between polysilicon and single crystal silicon.

Abstract: A capacitor dielectric can be between the storage node and the electrode layer. A supporting pattern can be connected to the storage node, where the supporting pattern can include at least one first pattern and at least one second pattern layered on one another, where the first pattern can include a material having an etch selectivity with respect to the second pattern.

Abstract: In a vertical dynamic memory cell, monocrystalline semiconductor material of improved quality is provided for the channel of an access transistor by lateral epitaxial growth over an insulator material (which complements the capacitor dielectric in completely surrounding the storage node except at a contact connection structure, preferably of metal, from the access transistor to the storage node electrode) and etching away a region of the lateral epitaxial growth including a location where crystal lattice dislocations are most likely to occur; both of which features serve to reduce or avoid leakage of charge from the storage node. An isolation structure can be provided in the etched region such that space is provided for connections to various portions of a memory cell array.

Abstract: Provided is a semiconductor device having a high switching speed. A semiconductor device is provided with an n-type epitaxial layer having a plurality of trenches arranged at prescribed intervals; an embedded electrode formed on an inner surface of the trench through a silicon oxide film to embed each trench; and a metal layer, which is capacitively coupled with the embedded electrode by being arranged above the embedded electrode through a silicon oxide film. In the semiconductor device, a region between the adjacent trenches operates as a channel (current path). A current flowing in the channel is interrupted by covering the region with a depletion layer formed at the periphery of the trenches, and the current is permitted to flow through the channel by eliminating the depletion layer at the periphery of the trenches.

Abstract: A layout of a semiconductor device is capable of reliably reducing a variation in gate length due to the optical proximity effect, and enables flexible layout design to be implemented. Gate patterns (G1, G2, G3) of a cell (C1) are arranged at the same pitch, and terminal ends (e1, e2, e3) of the gate patterns are located at the same position in the Y direction, and have the same width in the X direction. A gate pattern (G4) of a cell (C2) has protruding portions (4b) protruding toward the cell (C1) in the Y direction, and the protruding portions (4b) form opposing terminal ends (eo1, eo2, eo3). The opposing terminal ends (eo1, eo2, eo3) are arranged at the same pitch as the gate patterns (G1, G2, G3), are located at the same position in the Y direction, and have the same width in the X direction.

Abstract: In a semiconductor device which conducts multilevel writing operation and a driving method thereof, a signal line for controlling on/off of a writing transistor for conducting a writing operation on a memory cell using a transistor including an oxide semiconductor layer is disposed along a bit line, and a multilevel writing operation is conducted with use of, also in a writing operation, a voltage which is applied to a capacitor at a reading operation. Because an oxide semiconductor material that is a wide gap semiconductor capable of sufficiently reducing off-state current of a transistor is used, data can be held for a long period.

Abstract: A semiconductor device includes: a first interlayer insulating film; a first conductive member provided lower than the first interlayer insulating film; a contact plug that penetrates through the first interlayer insulating film, and is electrically connected to the first conductive member, the contact plug including a small-diameter part, and a large-diameter part arranged on the small-diameter part, an outer diameter of the large-diameter part being larger than an outer diameter of the small-diameter part, and the outer diameter of the large-diameter part being larger than an outer diameter of a connection face between the second conductive member and the large-diameter part; and a second conductive member that is provided on the first interlayer insulating film, and is electrically connected to the contact plug.

Abstract: A method of forming a memory cell including forming trenches in a layered semiconductor structure, each trench having an inner sidewall adjacent a section of the layered semiconductor structure between the trenches and an outer sidewall opposite the inner sidewall. The trenches are filled with polysilicon and the patterning layer is formed over the layered semiconductor structure. An opening is then patterned through the patterning layer, the opening exposing the section of the layered semiconductor structure between the trenches and only a vertical portion of the polysilicon along the inner sidewall of each trench. The layered semiconductor structure is then etched. The patterning layer prevents a second vertical portion of the polysilicon along the outer sidewall of each trench from being removed.

Abstract: A method of manufacturing a semiconductor device including forming on a substrate an insulating interlayer through which a capacitor contact is interposed; forming on the insulating interlayer a first upper electrode having an opening through which the capacitor contact is exposed; forming a first dielectric layer pattern on a lateral wall of the opening; forming a lower electrode on the first dielectric layer pattern formed in the opening and the capacitor contact; forming a second dielectric layer pattern on the lower electrode formed in the opening and the first dielectric layer pattern; and forming on the second dielectric layer pattern a second upper electrode so as to fill the opening and to contact the first upper electrode. The semiconductor device may prevent a lower electrode of a capacitor from collapsing.

Abstract: A semiconductor device includes a lower electrode, a supporting member enclosing at least an upper portion of the lower electrode, a dielectric layer on the lower electrode and the supporting member, and an upper electrode disposed on the dielectric layer. The supporting member may have a first portion that extends over an upper part of the sidewall of the lower electrode, and a second portion covering the upper surface of the lower electrode. The first portion of the supporting member protrudes above the lower electrode.

Abstract: Methods for capacitor fabrication include doping a capacitor region of a semiconductor layer in a semiconductor-on-insulator substrate; partially etching the semiconductor layer to produce a first terminal layer comprising doped semiconductor fins on a remaining base of doped semiconductor; forming a dielectric layer over the first terminal layer; and forming a second terminal layer over the dielectric layer in a finFET process.

Abstract: A semiconductor device has a non-volatile memory cell including a write transistor which includes an oxide semiconductor and has small leakage current in an off state (off-state current) between a source and a drain, a read transistor including a semiconductor material different from that of the write transistor, and a capacitor. Data is written or to the memory cell by applying a potential to a node where one of a source electrode and drain electrode of the write transistor, one electrode of the capacitor, and a gate electrode of the read transistor are electrically connected to one another so that the predetermined amount of charge is held in the node. The memory window width is changed by 2% or less, before and after 1×109 times of writing.

Abstract: Provided are an organic light emitting display device and a method of manufacturing the same. The organic light emitting display device includes a thin-film transistor (TFT), which includes an active layer, a gate electrode, and source/drain electrodes; an organic electroluminescent device electrically connected to the TFT and includes a pixel electrode formed on the same layer as the gate electrode, an intermediate layer including an organic light emitting layer, and a counter electrode that are stacked in the order stated; and a capacitor, which includes a bottom electrode, which is formed on the same layer and of the same material as the active layer and is doped with an impurity; a top electrode formed on the same layer as the gate electrode; and a metal diffusion medium layer formed on the same layer as the source/drain electrodes and is connected to the bottom electrode.

Abstract: A device includes a substrate having a front surface and a back surface opposite the front surface. A capacitor is formed in the substrate and includes a first capacitor plate; a first insulation layer encircling the first capacitor plate; and a second capacitor plate encircling the first insulation layer. Each of the first capacitor plate, the first insulation layer, and the second capacitor plate extends from the front surface to the back surface of the substrate.

Abstract: Disclosed are embodiments of an improved deep trench capacitor structure and memory device that incorporates this deep trench capacitor structure. The deep trench capacitor and memory device embodiments are formed on a semiconductor-on-insulator (SOI) wafer such that the insulator layer remains intact during subsequent deep trench etch processes and, optionally, such that the deep trench of the deep trench capacitor has different shapes and sizes at different depths. By forming the deep trench with different shapes and sizes at different depths the capacitance of the capacitor can be selectively varied and the resistance of the buried conductive strap which connects the capacitor to a transistor in a memory device can be reduced.

Abstract: A dual node dielectric trench capacitor includes a stack of layers formed in a trench. The stack of layers include, from bottom to top, a first conductive layer, a first node dielectric layer, a second conductive layer, a second node dielectric layer, and a third conductive layer. The dual node dielectric trench capacitor includes two back-to-back capacitors, which include a first capacitor and a second capacitor. The first capacitor includes the first conductive layer, the first node dielectric layer, the second conductive layer, and the second capacitor includes the second conductive layer, the second node dielectric layer, and the third conductive layer. The dual node dielectric trench capacitor can provide about twice the capacitance of a trench capacitor employing a single node dielectric layer having a comparable composition and thickness as the first and second node dielectric layers.

Abstract: A non-volatile memory device may include a first wordline on a substrate, an insulating layer on the first wordline, and a second wordline on the insulating layer so that the insulating layer is between the first and second wordlines. A bit pillar may extend adjacent the first wordline, the insulating layer, and the second wordline in a direction perpendicular with respect to a surface of the substrate, and the bit pillar may be electrically conductive. In addition, a first memory cell may include a first resistance changeable element electrically coupled between the first wordline and the bit pillar, and a second memory cell may include a second resistance changeable element electrically coupled between the second wordline and the bit pillar. Related methods and systems are also discussed.

Abstract: A semiconductor component includes a semiconductor body, in which are formed: a substrate of a first conduction type, a buried semiconductor layer of a second conduction type arranged on the substrate, and a functional unit semiconductor layer of a third conduction type arranged on the buried semiconductor layer, in which at least two semiconductor functional units arranged laterally alongside one another are provided. The buried semiconductor layer is part of at least one semiconductor functional unit, the semiconductor functional units being electrically insulated from one another by an isolation structure which permeates the functional unit semiconductor layer, the buried semiconductor layer, and the substrate. The isolation structure includes at least one trench and an electrically conductive contact to the substrate, the contact to the substrate being electrically insulated from the functional unit semiconductor layer and the buried layer by the at least one trench.