Abstract: The present invention proposes a semiconductor device structure and a method for manufacturing the same, and relates to the semiconductor manufacturing industry. The method comprises: providing a semiconductor substrate; forming gate electrode lines on the semiconductor substrate; forming sidewall spacers on both sides of the gate electrode lines; forming source/drain regions on the semiconductor substrates at both sides of the gate electrode lines; forming contact holes on the gate electrode lines or on the source/drain regions; and cutting off the gate electrode lines to form electrically isolated gate electrodes after formation of the sidewall spacers but before completion of FEOL process for a semiconductor device structure. The embodiments of the present invention are applicable for manufacturing integrated circuits.

Abstract: Processes for forming a tapered field plate dielectric in a semiconductor substrate are provided. The process may be used to form a variety of types of devices, such as Schottky diodes, HVFETs, JFET, IGBT, bipolar transistors, and the like. The process may include etching a trench in a semiconductor wafer, depositing an insulating layer on the semiconductor wafer to form a gap within the trench, depositing a masking layer on the insulating layer, and alternatingly etching the masking layer and the insulating layer to form a tapered field plate dielectric region.

Abstract: A process for fabricating a tapered field plate dielectric for high-voltage semiconductor devices is disclosed. The process may include depositing a thin layer of oxide, depositing a polysilicon hard mask, depositing a resist layer and etching a trench area, performing deep silicon trench etch, and stripping the resist layer. The process may further include repeated steps of depositing a layer of oxide and anisotropic etching of the oxide to form a tapered wall within the trench. The process may further include depositing poly and performing further processing to form the semiconductor device.

Abstract: A method for fin field effect transistor (finFET) device formation includes forming a plurality of fins on a substrate; forming a gate region over the plurality of fins; and forming isolation areas for the finFET device after formation of the gate region, wherein forming the isolation areas for the finFET device comprises performing one of oxidation or removal of a subset of the plurality of fins.

Abstract: An electronic device can include a tunnel structure that includes a first electrode, a second electrode, and tunnel dielectric layer disposed between the electrodes. In a particular embodiment, the tunnel structure may or may not include an intermediate doped region that is at the primary surface, abuts a lightly doped region, and has a second conductivity type opposite from and a dopant concentration greater than the lightly doped region. In another embodiment, the electrodes have opposite conductivity types. In a further embodiment, an electrode can be formed from a portion of a substrate or well region, and the other electrode can be formed over such portion of the substrate or well region.

Abstract: A reduction in material loss of trench isolation structures prior to forming a strain-inducing semiconductor alloy in transistor elements may result in superior device uniformity, for instance with respect to drive current and threshold voltage. To this end, at least one etch process using diluted hydrofluoric acid may be omitted when forming the shallow trench isolations, while at the same time providing a high degree of compatibility with conventional process strategies.

Abstract: Isolated and bulk semiconductor devices formed on a same bulk substrate and methods to form such devices are described. For example, a semiconductor structure includes a first semiconductor device having a first semiconductor body disposed on a bulk substrate. The first semiconductor body has an uppermost surface with a first horizontal plane. The semiconductor structure also includes a second semiconductor device having a second semiconductor body disposed on an isolation pedestal. The isolation pedestal is disposed on the bulk substrate. The second semiconductor body has an uppermost surface with a second horizontal plane. The first and second horizontal planes are co-planar.

Abstract: Embodiments of semiconductor devices and driver circuits include a semiconductor substrate having a first conductivity type, an isolation structure (including a sinker region and a buried layer), an active device within area of the substrate contained by the isolation structure, and a diode circuit. The buried layer is positioned below the top substrate surface, and has a second conductivity type. The sinker region extends between the top substrate surface and the buried layer, and has the second conductivity type. The active device includes a body region of the second conductivity type, and the diode circuit is connected between the isolation structure and the body region. The diode circuit may include one or more Schottky diodes and/or PN junction diodes. In further embodiments, the diode circuit may include one or more resistive networks in series and/or parallel with the Schottky and/or PN diode(s).

Abstract: Integrated circuits and methods for fabricating integrated circuits are provided. In an embodiment, a method for fabricating an integrated circuit includes providing an ultrathin body (UTB) fully depleted silicon-on-insulator (FDSOI) substrate. A PFET temporary gate structure and an NFET temporary gate structure are formed on the substrate. The method implants ions to form lightly doped active areas around the gate structures. A diffusionless annealing process is performed on the active areas. Further, a compressive strain region is formed around the PFET gate structure and a tensile strain region is formed around the NFET gate structure.

Abstract: A device and methods for forming a device are disclosed. The device includes a substrate having first, second and third regions. The first region includes a memory cell region, the second region includes a peripheral circuit region and the third region includes a logic region. A memory cell which includes a memory transistor having a first stack height (TSM) is disposed in the first region. A high voltage (HV) transistor having a second stack height (TSHV) is disposed in the second region and a logic transistor having a third stack height (TSL) is disposed in the third region. The first, second and third stack heights are substantially the same across the substrate.

Abstract: An apparatus of and method for making a semiconductor structure having a shallow trench isolation (STI) trench with a substantially v-shaped profile, that is the distance between top portions is greater than the distance between bottom portions of shallow trench isolation (STI) structure sidewalls adjacent to the trench, provides for substantially seamless and substantially void-free gate structures. The semiconductor structures are formed by implanting an implantation species into the sidewalls, which allows for the top portions of the sidewalls to be etched away at a greater rate than that of the bottom portions, resulting in the substantially v-shaped profile. And the substantially v-shaped profile allows for subsequent device layers to more easily and smoothly fill in the v-shaped trenches, due to a wider opening toward the tops of the trenches.

Abstract: A method of making a semi-insulating epitaxial layer includes implanting a substrate or a first epitaxial layer formed on the substrate with boron ions to form a boron implanted region on a surface of the substrate or on a surface of the first epitaxial layer, and growing a second epitaxial layer on the boron implanted region of the substrate or on the boron implanted region of the first epitaxial layer to form a semi-insulating epitaxial layer.

Abstract: A semiconductor device with a field electrode and method. One embodiment provides a controllable semiconductor device including a control electrode for controlling the semiconductor device and a field electrode. The field electrode includes a number of longish segments which extend in a first lateral direction and which run substantially parallel to one another. The control electrode includes a number of longish segments extending in a second lateral direction and running substantially parallel to one another, wherein the first lateral direction is different from the second lateral direction.

Abstract: A method for fabricating a CMOS device includes the following steps. A wafer is provided. STI is used to form at least one active area in the wafer. A silicon oxide layer is deposited onto the wafer covering the active area. A first high-k material is deposited onto the silicon oxide layer. Portions of the silicon oxide layer and the first high-k material are selectively removed, such that the silicon oxide layer and the first high-k material remain over one or more first regions of the active area and are removed from over one or more second regions of the active area. A second high-k material is deposited onto the first high-k material over the one or more first regions of the active area and onto a surface of the wafer in the one or more second regions of the active area. A CMOS device is also provided.

Abstract: A semiconductor structure comprises a substrate having a first conductive type; a deep well having a second conductive type formed in the substrate and extending down from a surface of the substrate; a first well having the first conductive type and a second well having the second conductive type both formed in the deep well and extending down from the surface of the substrate, and the second well spaced apart from the first well; a gate electrode formed on the substrate and disposed between the first and second wells; an isolation extending down from the surface of the substrate and disposed between the gate electrode and the second well; a conductive plug including a first portion and a second portion electrically connected to each other, and the first portion electrically connected to the gate electrode, and the second portion penetrating into the isolation.

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: Generally, the present disclosure is directed to various methods of recessing an active region and an adjacent isolation structure in a common etch process. One illustrative method disclosed includes forming an isolation structure in a semiconducting substrate, wherein the isolation structure defines an active area in the substrate, forming a patterned masking layer above the substrate, wherein the patterned masking layer exposes the active area and at least a portion of the isolation structure for further processing, and performing a non-selective dry etching process on the exposed active area and the exposed portion of the isolation structure to define a recess in the substrate and to remove at least some of the exposed portions of the isolation structure.

Abstract: Methods of forming semiconductor structures that include bodies of a semiconductor material disposed between rails of a dielectric material are disclosed. Such methods may include filling a plurality of trenches in a substrate with a dielectric material and removing portions of the substrate between the dielectric material to form a plurality of openings. In some embodiments, portions of the substrate may be undercut to form a continuous void underlying the bodies and the continuous void may be filled with a conductive material. In other embodiments, portions of the substrate exposed within the openings may be converted to a silicide material to form a conductive material under the bodies. For example, the conductive material may be used as a conductive line to electrically interconnect memory device components. Semiconductor structures and devices formed by such methods are also disclosed.

Abstract: Embodiments disclosed herein may relate to forming a base contact layout in a memory device.

Abstract: A device includes a semiconductor substrate, a channel region in the semiconductor substrate having a first conductivity type, and a composite drift region in the semiconductor substrate, having a second conductivity type. The composite drift region includes a first drift region and a second drift region spaced from the channel region by the first drift region. The device further includes a drain region in the semiconductor substrate, spaced from the channel region by the composite drain region, and having the second conductivity type. The first drift region has a dopant concentration profile with a first concentration level where adjacent the channel region and a second concentration level where adjacent the second drift region, the first concentration level being higher than the second concentration level. In some embodiments, the first and second drift regions are stacked vertically, with the first drift region being shallower than the second drift region.

Abstract: A method of semiconductor device fabrication including forming a plurality of gate structures in a first portion of a substrate, wherein the plurality of gate structures have a first height. A first metal gate structure is formed in a second portion of the substrate, the first metal gate structure being surrounded by an isolation region. A plurality of dummy gate structures is formed in the second portion of the substrate. The plurality of dummy gate structures are configured in a ring formation encircling the metal gate structure and the isolation region. The plurality of dummy structures have a top surface that is substantially planar with the plurality of gate structures and covers at least 5% of a pattern density of the second portion of the substrate.

Abstract: A semiconductor device and method for fabricating a semiconductor device are disclosed.

Abstract: System and method for forming lightly doped drain (LDD) extensions. An embodiment comprises forming a gate electrode on a semiconductor fin and forming a dielectric layer over the gate electrode. The gate electrode is then etched to expose a portion of the semiconductor fin. The exposed portions of the fin comprise the LDD extensions.

Abstract: In one embodiment, a semiconductor device includes a semiconductor substrate, isolation regions disposed in the semiconductor substrate, and device regions disposed between the isolation regions in the semiconductor substrate. The device further includes a first line disposed on the device regions and the isolation regions, a line width of the first line on the isolation regions being larger than a line width of the first line on the device regions.

Abstract: According to one embodiment, a manufacturing method of a semiconductor device includes forming a lower mask film on a semiconductor substrate. The method includes forming a barrier film in a first area. The method includes forming an upper mask film. The method includes removing an upper mask member and leaving a lower mask member in the first area and removing the upper mask member and the lower mask member in the second area. The removing is performed by etching in a condition in which an etching rate of the upper mask member and an etching rate of the lower mask member are higher than that of the barrier member. The method includes forming a conductive film. The method includes selectively removing the conductive film by performing etching in a condition in which an etching rate of the conductive film is higher than that of the lower mask member.

Abstract: The present invention discloses a method for lift-off of an LED substrate. By eroding the sidewall of a GaN epitaxial layer, cavity structures are formed, which may act in cooperation with a non-fully filled patterned sapphire substrate from epitaxial growth to cause the GaN epitaxial layer to separate from the sapphire substrate. The method according to an embodiment of the present invention can effectively reduce the dislocation density in the growth of a GaN-based epitaxial layer; improve lattice quality, and realize rapid lift-off of an LED substrate, and has the advantages including low cost, no internal damage to the GaN film, elevated performance of the photoelectric device and improved luminous efficiency.

Abstract: A preparation method for a full-isolated silicon on insulator (SOI) substrate with hybrid crystal orientations and a preparation method of a complementary metal oxide semiconductor (CMOS) integrated circuit (IC) based on the method are disclosed. In the preparation method for the full-isolated SOI substrate with hybrid crystal orientations provided in the present invention, a SiGe layer is adopted to serve as an epitaxial virtual substrate layer with a first crystal orientation, so as to form a strained top silicon with the first crystal orientation; a polysilicon supporting material is adopted to serve as a support for connecting the top silicon with the first crystal orientation and a top silicon with a second crystal orientation, so that the SiGe layer below the strained top silicon with the first crystal orientation may be removed, and an insulating material is filled to form an insulating buried layer.

Abstract: A method that includes forming a masking element on a semiconductor substrate and overlying a defined space. A first feature and a second feature are each formed on the semiconductor substrate. The space interposes the first and second features and extends from a first end of the first feature to a first end of the second feature. A third feature is then formed adjacent and substantially parallel the first and second features. The third feature extends at least from the first end of the first feature to the first end of the second feature.

Abstract: A device includes a semiconductor fin, a gate dielectric on sidewalls of the semiconductor fin, a gate electrode over the gate dielectric, and isolation regions. The isolation regions include a first portion on a side of the semiconductor fin, wherein the first portion is underlying and aligned to a portion of the gate electrode. The semiconductor fin is over a first top surface of the first portion of the isolation regions. The isolation regions further include second portions on opposite sides of the portion of the gate electrode. The second top surfaces of the second portions of the isolation regions are higher than the first top surface of the isolation regions.

Abstract: A semiconductor device structure and a method for manufacturing the same are disclosed. In one embodiment, the method comprises: forming a fin in a first direction on a semiconductor substrate; forming a gate line in a second direction crossing the first direction on the semiconductor substrate, the gate line intersecting the fin via a gate dielectric layer; forming a dielectric spacer surrounding the gate line; forming a conductive spacer surrounding the dielectric spacer; and performing inter-device electrical isolation at a predetermined region, wherein isolated portions of the gate line form gate electrodes of respective unit devices, and isolated portions of the conductive spacer form contacts of the respective unit devices.

Abstract: Disclosed is a Zener diode having a scalable reverse-bias breakdown voltage (Vb) as a function of the position of a cathode contact region relative to the interface between adjacent cathode and anode well regions. Specifically, cathode and anode contact regions are positioned adjacent to corresponding cathode and anode well regions and are further separated by an isolation region. However, while the anode contact region is contained entirely within the anode well region, one end of the cathode contact region extends laterally into the anode well region. The length of this end can be predetermined in order to selectively adjust the Vb of the diode (e.g., increasing the length reduces Vb of the diode and vice versa). Also disclosed are an integrated circuit, incorporating multiple instances of the diode with different reverse-bias breakdown voltages, a method of forming the diode and a design structure for the diode.

Abstract: A semiconductor device includes a substrate including a cavity and a first material layer over at least a portion of sidewalls of the cavity. The semiconductor device includes an oxide layer over the substrate and at least a portion of the sidewalls of the cavity such that the oxide layer lifts off a top portion of the first material layer toward a center of the cavity.

Abstract: A semiconductor device includes a first transistor including a first source/drain region and a first sidewall spacer, and a second transistor including a second source/drain region and a second sidewall spacer, the first sidewall spacer has a first width and the second sidewall spacer has a second width wider than the first width, and the first source/drain region has a first area and the second source/drain region has a second area larger than the first area.

Abstract: A semiconductor device and a method for fabricating the same are disclosed. The method for fabricating the semiconductor device includes forming an shallow trench isolation (STI) in a substrate, sequentially forming an oxide layer and a nitride layer over the substrate, patterning the nitride layer and the oxide layer to expose a portion of the substrate adjacent to the STI layer, forming a field oxide layer contacting the STI layer in the exposed portion of the substrate, removing the nitride layer, etching a portion of the patterned oxide layer to form a first gate oxide layer contacting the field oxide layer, forming a second gate oxide layer over the substrate, and forming a gate pattern over the field oxide layer, the first gate oxide layer, and the second gate oxide layer.

Abstract: According to one embodiment, firstly, an inversion pattern having a periodic pattern in which a first line pattern and a space are inversed and a non-periodic pattern arranged at an interval which is substantially equal to the width of the first line pattern from the end of the periodic pattern is formed above a processing object so as to correspond to the plurality of spaces between a plurality of first line patterns in a first pattern and the space between the first pattern and a second pattern. Next, a sidewall film is formed around the inversion pattern, and the periodic pattern is removed selectively. Thereafter, the processing object is etched using the sidewall pattern formed of the sidewall film and the non-periodic pattern surrounded by the sidewall film as masks.

Abstract: A substrate includes a first region having a first resistivity, for optimizing a field effect transistor, a second region having a second resistivity, for optimizing an npn subcollector of a bipolar transistor device and triple well, a third region having a third resistivity, with a high resistivity for a passive device, a fourth region, substantially without implantation, to provide low perimeter capacitance for devices.

Abstract: A method of fabricating a semiconductor device includes the following steps. A semiconductor substrate having a first side and a second side facing to the first side is provided. At least an opening is disposed in the semiconductor substrate of a protection region defined in the first side. A first material layer is formed on the first side and the second side, and the first material layer partially fills the opening. Subsequently, a part of the first material layer on the first side and outside the protection region is removed. A second material layer is formed on the first side and the second side, and the second material layer fills the opening. Then, a part of the second material layer on the first side and outside the protection region is removed. Finally, the remaining first material layer and the remaining second material layer on the first side are planarized.

Abstract: A process is described for wavelength conversion of LED light using phosphors. LED dies are tested for correlated color temperature (CCT), and binned according to their color emission. The LEDs in each_bin are mounted on a single submount to form an array of LEDs. Various thin sheets of a flexible encapsulant (e.g., silicone) infused with one or more phosphors are preformed, where each sheet has different color conversion properties. An appropriate sheet is placed over an array of LED mounted on a submount, and the LEDs are energized. The resulting light is measured for CCT. If the CCT is acceptable, the phosphor sheet is permanently laminated onto the LEDs and submount. By selecting a different phosphor sheet for each bin of LEDs, the resulting CCT is very uniform across all bins.

Abstract: An electrical characteristics test for a semiconductor integrated circuit using a Kelvin contact method can be conducted in a pre-process without obstructing the reduction in size of a semiconductor chip or without complicating the circuit design. A probe card in a testing apparatus includes probes for Kelvin contact, the probes for Kelvin contact including a coil probe and a POGO pin probe disposed inside the coil probe, and a probe for two-terminal measurement. Electrode pads formed in each chip area over a wafer are in a relation of A=B<2A, given that the area of one of the electrode pads with which the probe for Kelvin contact comes into contact is B and the area of the other electrode pad with which the probe for two-terminal measurement comes into contact is A.

Abstract: A mechanically robust semiconductor structure with improved adhesion strength between a low-k dielectric layer and a dielectric-containing substrate is provided. In particular, the present invention provides a structure that includes a dielectric-containing substrate having an upper region including a treated surface layer which is chemically and physically different from the substrate; and a low-k dielectric material located on a the treated surface layer of the substrate. The treated surface layer and the low-k dielectric material form an interface that has an adhesion strength that is greater than 60% of the cohesive strength of the weaker material on either side of the interface. The treated surface is formed by treating the surface of the substrate with at least one of actinic radiation, a plasma and e-beam radiation prior to forming of the substrate the low-k dielectric material.

Abstract: A semiconductor process for removing oxide layers comprises the steps of providing a substrate having an isolation structure and a pad oxide layer, performing a dry cleaning process and a wet cleaning process to remove said pad oxide layer, forming a sacrificial oxide layer on said substrate, and performing an ion implantation process to form doped well regions on both sides of the isolation structure.

Abstract: A method of substantially uniformly removing silicon oxide is disclosed. The silicon oxide to be removed includes at least one cavity therein or more than one density or strain therein. The silicon oxide having the at least one cavity or more than one density or strain is exposed to a gaseous mixture of NH3 and HF and heated, to substantially uniformly remove the silicon oxide. A method of removing an exposed sacrificial layer without substantially removing exposed isolation regions using the gaseous mixture of NH3 and HF and heat is also disclosed, as is an intermediate semiconductor device structure that includes a semiconductor substrate, a sacrificial layer overlying the semiconductor substrate, a diffusion barrier overlying the sacrificial layer, and exposed isolation regions.

Abstract: A method of manufacturing a semiconductor device structure, such as a FinFET device structure, is provided. The method begins by providing a substrate comprising a bulk semiconductor material, a first conductive fin structure formed from the bulk semiconductor material, and a second conductive fin structure formed from the bulk semiconductor material. The first conductive fin structure and the second conductive fin structure are separated by a gap. Next, spacers are formed in the gap and adjacent to the first conductive fin structure and the second conductive fin structure. Thereafter, an etching step etches the bulk semiconductor material, using the spacers as an etch mask, to form an isolation trench in the bulk semiconductor material. A dielectric material is formed in the isolation trench, over the spacers, over the first conductive fin structure, and over the second conductive fin structure.

Abstract: A method for formation of a semiconductor device including a first mono-crystalline layer comprising first transistors and first alignment marks, the method comprising forming a doped layer within a wafer, forming a second mono-crystalline layer on top of the first mono-crystalline layer by transferring at least a portion of the doped layer using layer transfer step, and processing second transistors on the second mono-crystalline layer comprising a step of forming a gate dielectric, wherein the second transistors are horizontally oriented.

Abstract: A structure includes a substrate comprising a region having a circuit or device which is sensitive to electrical noise. Additionally, the structure includes a first isolation structure extending through an entire thickness of the substrate and surrounding the region and a second isolation structure extending through the entire thickness of the substrate and surrounding the region.

Abstract: A preparation method for a full-isolated silicon on insulator (SOI) substrate with hybrid crystal orientations and a preparation method of a complementary metal oxide semiconductor (CMOS) integrated circuit (IC) based on the method are disclosed. In the preparation method for the full-isolated SOI substrate with hybrid crystal orientations provided in the present invention, a SiGe layer is adopted to serve as an epitaxial virtual substrate layer with a first crystal orientation, so as to form a strained top silicon with the first crystal orientation; a polysilicon supporting material is adopted to serve as a support for connecting the top silicon with the first crystal orientation and a top silicon with a second crystal orientation, so that the SiGe layer below the strained top silicon with the first crystal orientation may be removed, and an insulating material is filled to form an insulating buried layer.

Abstract: A method of manufacturing a semiconductor device is disclosed. The exemplary method includes providing a substrate having a source region and a drain region. The method further includes forming a first recess in the substrate within the source region and a second recess in the substrate within the drain region. The first recess has a first plurality of surfaces and the second recess has a second plurality of surfaces. The method also includes epi-growing a semiconductor material in the first and second recesses and, thereafter, forming shallow isolation (STI) features in the substrate.

Abstract: A unit block circuit of a semiconductor device includes a first well, a first pickup unit configured to form a closed loop over the first well, a first transistor including a first gate and a first active region, and formed within the first pickup unit, and a first reservoir capacitor formed in a spare within the first pickup unit and arranged in a major-axis direction of the first gate of the first transistor, wherein the first reservoir capacitor comprises a second active region and a second gate, the second gate being formed over the second active region.

Abstract: According to one embodiment, a semiconductor memory includes a memory cell provided in a first active area surrounded with a first isolation insulating film, a first transistor provided in a second active area surrounded with a second isolation insulating film, a shield gate electrode on the second isolation insulating film. The bottom surface of the shield gate electrode is positioned more closely to a semiconductor substrate side as compared with the highest upper surface of the second isolation insulating film.

Abstract: According to one embodiment of the disclosure, a method for passivating a circuit device generally includes providing a substrate having a substrate surface, forming an electrical component on the substrate surface, and coating the substrate surface and the electrical component with a first protective dielectric layer. The first protective dielectric layer is made of a generally moisture insoluble material having a moisture permeability less than 0.01 gram/meter2/day, a moisture absorption less than 0.04 percent, a dielectric constant less than 10, a dielectric loss less than 0.005, a breakdown voltage strength greater than 8 million volts/centimeter, a sheet resistivity greater than 1015 ohm-centimeter, and a defect density less than 0.5/centimeter2.