| Patent application number | Description | Published |
|---|
| 20090166728 | Structure and Method for Forming Shielded Gate Trench FET with Multiple Channels - A field effect transistor (FET) includes a pair of trenches extending into a semiconductor region. Each trench includes a first shield electrode in a lower portion of the trench and a gate electrode in an upper portion of the trench over but insulated from the shield electrode. First and second well regions of a first conductivity type laterally extend in the semiconductor region between the pair of trenches and abut sidewalls of the pair of trenches. The first and second well regions are vertically spaced from one another by a first drift region of a second conductivity type. The gate electrode and the first shield electrode are positioned relative to the first and second well regions such that a channel is formed in each of the first and second well regions when the FET is biased in the on state. | 07-02-2009 |
| 20090189218 | Structure and Method for Forming Power Devices with High Aspect Ratio Contact Openings - A field effect transistor (FET) includes body regions of a first conductivity type over a semiconductor region of a second conductivity type. Source regions of the second conductivity type extend over the body regions. Gate electrodes extend adjacent to but are insulated from the body regions by a gate dielectric layer. Contact openings extend into the body regions between adjacent gate electrodes. A seed layer extends along the bottom of each contact opening. The seed layer serves as a nucleation site for promoting growth of conductive fill material. A conductive fill material fills a lower portion of each contact opening. An interconnect layer fills an upper portion of each contact opening and is in direct contact with the conductive fill material. The interconnect layer is also in direct contact with corresponding source regions along upper sidewalls of the contact openings. | 07-30-2009 |
| 20090194811 | Structure and Method for Forming Field Effect Transistor with Low Resistance Channel Region - A trench-gate field effect transistor includes trenches extending into a silicon region of a first conductivity type, and a gate electrodes in each trench. Body regions of second conductivity type extend over the silicon region between adjacent trenches. Each body region forms a first PN junction with the silicon region, and each body region includes a silicon-germanium layer of the second conductivity type laterally extending between adjacent trenches. Source regions of the first conductivity flank the trenches, and each source region forms a second PN junction with one of the body regions. Channel regions extend in the body regions along sidewalls of the trenches between the source regions and a bottom surface of the body regions. The silicon-germanium layers extend into corresponding channel regions to thereby reduce the channel resistance. | 08-06-2009 |
| 20090267146 | STRUCTURE AND METHOD FOR SEMICONDUCTOR POWER DEVICES - A semiconductor device includes a semiconductor-on-insulator region on a substrate. The semiconductor-on-insulator region includes a first semiconductor region overlying a dielectric region. The device includes an MOS transistor and a bipolar transistor. The MOS transistor has a drain region, a body region, and a source region in the first semiconductor region. The MOS transistor also includes a gate. The device also includes a second semiconductor region overlying the substrate and adjacent to the drain region, and a third semiconductor region overlying the substrate and adjacent to the second semiconductor region. The bipolar transistor includes has the drain region of the MOS transistor as an emitter, the second semiconductor region as a base, and the third semiconductor region as a collector. Accordingly, the drain of the MOS transistor also functions as the emitter of the bipolar transistor. Additionally, the gate and the base are coupled by a resistive element. | 10-29-2009 |
| 20090269896 | Technique for Controlling Trench Profile in Semiconductor Structures - A method for forming a semiconductor structure includes the following steps. Trenches are formed in a semiconductor region using a masking layer such that the trenches have a first depth, a first width along their bottom, and sidewalls having a first slope. The masking layer is removed, and a bevel etch is performed to taper the sidewalls of the trenches so that the sidewalls have a second slope less than the first slope. | 10-29-2009 |
| 20090302381 | Structure and Method for Forming Power Devices with Carbon-containing Region - A field effect transistor (FET) includes body regions of a first conductivity type over a semiconductor region of a second conductivity type. The body regions form p-n junctions with the semiconductor region. Source regions of the second conductivity type extend over the body regions. The source regions form p-n junctions with the body regions. Gate electrodes extend adjacent to but are insulated from the body regions by a gate dielectric. A carbon-containing region extends in the semiconductor region below the body regions. | 12-10-2009 |
| 20090315083 | Structure and Method for Forming a Thick Bottom Dielectric (TBD) for Trench-Gate Devices - A semiconductor structure which includes a trench gate FET is formed as follows. A plurality of trenches is formed in a semiconductor region using a mask. The mask includes (i) a first insulating layer over a surface of the semiconductor region, (ii) a first oxidation barrier layer over the first insulating layer, and (iii) a second insulating layer over the first oxidation barrier layer. A thick bottom dielectric (TBD) is formed along the bottom of each trench. The first oxidation barrier layer prevents formation of a dielectric layer along the surface of the semiconductor region during formation of the TBD. | 12-24-2009 |
| 20100006928 | Structure and Method for Forming a Shielded Gate Trench FET with an Inter-electrode Dielectric Having a Low-k Dielectric Therein - A shielded gate trench field effect transistor (FET) comprises trenches extending into a semiconductor region. A shield electrode is disposed in a bottom portion of each trench. The shield electrode is insulated from the semiconductor region by a shield dielectric. A gate electrode is disposed in each trench over the shield electrode, and an inter-electrode dielectric (IED) comprising a low-k dielectric extends between the shield electrode and the gate electrode. | 01-14-2010 |
| 20100013009 | Structure and Method for Forming Trench Gate Transistors with Low Gate Resistance - A field effect transistor includes body regions of a first conductivity type over a semiconductor region of a second conductivity type such that the body regions form p-n junctions with the semiconductor region. Trenches extend through the body region and terminate within the semiconductor region. Source regions of the second conductivity type extend over the body regions adjacent the trenches such that the source regions form p-n junctions with the body regions. A gate dielectric layer lines sidewalls of each trench. A metal liner lines the gate dielectric layer in each trench. A gate electrode comprising metallic material is disposed in each trench. | 01-21-2010 |
| 20100065904 | High density trench field effect transistor - A semiconductor structure comprises trenches extending into a semiconductor region. Portions of the semiconductor region extend between adjacent trenches forming mesa regions. A gate electrode is in each trench. Well regions of a first conductivity type extend in the semiconductor region between adjacent trenches. Source regions of a second conductivity type are in the well regions. Heavy body regions of the first conductivity type are in the well regions. The source regions and the heavy body regions are adjacent trench sidewalls, and the heavy body regions extend over the source regions along the trench sidewalls to a top surface of the mesa regions. | 03-18-2010 |
| 20100065905 | Structures and Methods for Reducing Dopant Out-diffusion from Implant Regions in Power Devices - A semiconductor structure comprises a drift region of a first conductivity type in a semiconductor region. A well region of a second conductivity type is over the drift region. A source region of the first conductivity type is in an upper portion of the well region. A heavy body region of the second conductivity type extends in the well region. The heavy body region has a higher doping concentration than the well region. A first diffusion barrier region at least partially surrounds the heavy body region. A gate electrode is insulated from the semiconductor region by a gate dielectric. | 03-18-2010 |
| 20100238743 | FAST EMBEDDED BiCMOS-THYRISTOR LATCH-UP NONVOLATILE MEMORY - This disclosure describes a new semiconductor non-volatile memory that can be potentially faster than DRAM and FLASH, and the manufacturing cost can be lower than SRAM, which is volatile. It is possible to fabricate an ULSI microprocessor and this type of new memory array in the same chip—realizing the “embedded” process. There are a CMOS transistor and latched-up Bipolar transistors (A thyristor) in the device. The fast read, write and erase operations are done by charging the MOS gate capacitor interface and sensing the latch-up voltage of the thyristor. The latch-up voltage of the thyristor is reduced for the additional MOSFET current during the write process, causing early avalanche breakdown and the latch-up of the bipolar transistors. The semiconductor memory can be fabricated as a planar device or a vertical device. | 09-23-2010 |
| 20100252876 | Structure and method for forming an oscillating MOS transistor and nonvolatile memory - With simply applying the gate voltage, the transistor will start sending out oscillating signals, working like a semiconductor “engine”. A special MOS field effect transistor (FET) includes an extended lightly doped drain and an intrinsic undoped or very lightly doped “gap” between the gate and the heavily doped source. The gap needs to be specially engineered so that the transistor is not always turned on by the MOSFET gate voltage, but will be turned on by the carriers from the forward-biased channel-drain junction diode. Oscillation occurs to the drain current (or voltage) when a suitable gate voltage is applied, due to the repeated back and forth actions of deep depletion in the transistor well and forward bias of the drain-well p-n junction diode. By forming a second spacer gate on one side of the main gate, the device can be used as a non-volatile memory, with the charges stored at the dielectrics / silicon interface, which can significantly impact the oscillating for the READ operation of a memory. This device can also be a frequency amplifier. | 10-07-2010 |
| 20100258866 | Method for Forming Shielded Gate Trench FET with Multiple Channels - A method of forming a field effect transistor (FET) includes the following steps. A pair of trenches extending into a semiconductor region of a first conductivity type is formed. A shield electrode is formed in a lower portion of each trench. A gate electrode is formed in an upper portion of each trench over but insulated from the shield electrode. First and second well regions of a second conductivity type are formed in the semiconductor region between the pair of trenches such that the first and second well regions are vertically spaced from one another and laterally abut sidewalls of the pair of trenches. The gate electrode and the first shield electrode are formed relative to the first and second well regions such that a channel is formed in each of the first and second well regions when the FET is biased in the on state. | 10-14-2010 |
| 20100296540 | Resonant Cavity Complementary Optoelectronic Transistors - The CMOS field effect transistors, used in microprocessors and other digital VLSI circuits, face major challenges such as thin gate dielectrics leakage and scaling limits, severe short channel effects, limited performance improvement with scaling, complicated fabrication process with added special techniques, and surface mobility degradation. This disclosure proposes a new CMOS-compatible optoelectronic transistor. The current is much higher than the MOS transistors, due to the high carrier mobility with bulk transportation. The optoelectronic transistors are scalable to the sub-nanometer ranges without short channel effects. It is also suitable for low power applications and ULSI circuits. The new transistor consists of a laser or LED diode as drain or source, and a photo sensor diode (avalanche photo diode) as source or drain. The transistor is turned on by applying a gate voltage, similar to the CMOS transistors, and a laser or LED light signal is sent to the nearby photo diode, causing an avalanche breakdown and high drain current. The transistor is surrounded by dielectrics and metal isolations, which serve as a metal box or cavity, so the generated laser or LED lights are confined and reflected back from the metal. The drain current increases exponentially with the drain or gate voltage. This exponential drain current vs. drain or gate voltage characteristics makes the optoelectronic transistor run much faster than the transitional linear MOSFET. | 11-25-2010 |
| 20100320534 | Structure and Method for Forming a Thick Bottom Dielectric (TBD) for Trench-Gate Devices - A semiconductor structure which includes a shielded gate FET is formed as follows. A plurality of trenches is formed in a semiconductor region using a mask. The mask includes (i) a first insulating layer over a surface of the semiconductor region, (ii) a first oxidation barrier layer over the first insulating layer, and (iii) a second insulating layer over the first oxidation barrier layer. A shield dielectric is formed extending along at least lower sidewalls of each trench. A thick bottom dielectric (TBD) is formed along the bottom of each trench. The first oxidation barrier layer prevents formation of a dielectric layer along the surface of the semiconductor region during formation of the TBD. A shield electrode is formed in a bottom portion of each trench. A gate electrode is formed over the shield electrode in each trench. | 12-23-2010 |
| 20110012174 | Structure and Method for Forming Field Effect Transistor with Low Resistance Channel Region - A trench-gate field effect transistor includes trenches extending into a silicon region of a first conductivity type, and a gate electrodes in each trench. Body regions of second conductivity type extend over the silicon region between adjacent trenches. Each body region forms a PN junction with the silicon region. A gate dielectric layer lines at least upper sidewalls of each trench, and insulates the gate electrode from the body region. Source regions of the first conductivity flank the trenches. A silicon-germanium region vertically extends through each source region and through a corresponding body region, and terminates within the corresponding body region before reaching the PN junction. | 01-20-2011 |
| 20110133275 | STRUCTURE AND METHOD FOR SEMICONDUCTOR POWER DEVICES - A semiconductor device includes a semiconductor-on-insulator region on a substrate. The semiconductor-on-insulator region includes a first semiconductor region overlying a dielectric region. The device includes an MOS transistor and a bipolar transistor. The MOS transistor has a drain region, a body region, and a source region in the first semiconductor region. The MOS transistor also includes a gate. The device also includes a second semiconductor region overlying the substrate and adjacent to the drain region, and a third semiconductor region overlying the substrate and adjacent to the second semiconductor region. The bipolar transistor includes has the drain region of the MOS transistor as an emitter, the second semiconductor region as a base, and the third semiconductor region as a collector. Accordingly, the drain of the MOS transistor also functions as the emitter of the bipolar transistor. Additionally, the gate and the base are coupled by a resistive element. | 06-09-2011 |
