Patent application number | Description | Published |
20080233748 | ETCH DEPTH DETERMINATION FOR SGT TECHNOLOGY - A method for determining the depth etch, a method of forming a shielded gate trench (SGT) structure and a semiconductor device wafer are disclosed. A material layer is formed over part of a substrate having a trench. The material fills the trench. A resist mask is placed over a test portion of the layer of material. The resist mask does not cover the trench. The layer of material is isotropically etched. An etch depth may be determined from a characteristic of etching of the material underneath the mask. Such a method may be used for forming SGT structures. The wafer may comprise a layer of material disposed on at least a portion of a surface of semiconductor wafer; a resist mask comprising an angle-shaped test portion disposed over a portion of the layer of material; and a ruler marking on the surface of the substrate proximate the test portion. | 09-25-2008 |
20080272371 | RESISTANCE-BASED ETCH DEPTH DETERMINATION FOR SGT TECHNOLOGY - A method for determining the depth etch, a method of forming a shielded gate trench (SGT) structure and a semiconductor device wafer are disclosed. A material layer is formed over part of a substrate having a trench. The material fills the trench. A resist mask is placed over a test portion of the material layer thereby defining a test structure that lies underneath the resist mask. The resist mask does not cover the trench. The material is isotropically etched and a signal related to a resistance change of the test structure is measured. A lateral undercut D | 11-06-2008 |
20090148995 | Processes for manufacturing MOSFET devices with excessive round-hole shielded gate trench (SGT) - This invention discloses an improved method for manufacturing a trenched metal oxide semiconductor field effect transistor (MOSFET) device. The method includes a step of opening a trench in substrate and covering trench walls of the trench with a linen layer followed by removing a portion of the linen layer from a bottom portion of the trench. The method further includes a step of opening a round hole by applying an isotropic substrate etch on the bottom portion of the trench with the round hole extending laterally from the trench walls. The method further includes a step of filling the trench and the round hole at the bottom of the trench with a gate material followed by applying a time etch to removed the gate material from a top portion of the trench whereby the gate material only filling the round hole up to a lateral expansion point of the round hole. | 06-11-2009 |
20090166621 | RESISTANCE-BASED ETCH DEPTH DETERMINATION FOR SGT TECHNOLOGY - A method for determining the depth etch, a method of forming a shielded gate trench (SGT) structure and a semiconductor device wafer are disclosed. A material layer is formed over part of a substrate having a trench. The material fills the trench. A resist mask is placed over a test portion of the material layer thereby defining a test structure that lies underneath the resist mask. The resist mask does not cover the trench. The material is isotropically etched and a signal related to a resistance change of the test structure is measured. A lateral undercut D | 07-02-2009 |
20090256149 | Structure for Measuring Body Pinch Resistance of High Density Trench MOSFET Array - A structure is disclosed for measuring body pinch resistance Rp of trench MOSFET arrays on a wafer. The trench MOSFET array has a common drain layer of first conductivity type and a 2D-trench MOSFET array atop the common drain layer. The 2D-trench MOSFET array has an interdigitated array of source-body columns and gate trench columns. Each source-body column has a bottom body region of second conductivity type with up-extending finger structures. Each source-body column has top source regions of first conductivity type bridging the finger structures. The structure includes:
| 10-15-2009 |
20100084707 | Polysilicon control etch-back indicator - This invention discloses a semiconductor wafer for manufacturing electronic circuit thereon. The semiconductor substrate further includes an etch-back indicator that includes trenches of different sizes having polysilicon filled in the trenches and then completely removed from some of the trenches of greater planar trench dimensions and the polysilicon still remaining in a bottom portion in some of the trenches having smaller planar trench dimensions. | 04-08-2010 |
20100105182 | Shallow source MOSFET - Fabricating a semiconductor device includes forming a hard mask on a substrate having a top substrate surface, forming a trench in the substrate through the hard mask, depositing gate material in the trench, where the amount of gate material deposited in the trench extends beyond the top substrate surface, and removing the hard mask to leave a gate having a gate top surface that extends substantially above the top substrate surface at least in center region of the trench opening, the gate having a vertical edge that includes an extended portion, the extended portion extending above the trench opening and being substantially aligned with the trench wall. It further includes implanting a body, implanting a plurality of source regions embedded in the body, forming a plurality of spacers that insulate the source regions from the gate, the plurality of spacers being situated immediately adjacent to the gate and immediately adjacent to respective ones of the plurality of source regions, wherein the plurality of spacers do not substantially extend into the trench and do not substantially extend over the trench, disposing a dielectric layer over the source, the spacers, the gate, and at least a portion of the body, forming a contact opening, and disposing metal to form a contact with the body at the contact opening. | 04-29-2010 |
20100148246 | Power mosfet device structure for high frequency applications - This invention discloses a new switching device supported on a semiconductor that includes a drain disposed on a first surface and a source region disposed near a second surface of said semiconductor opposite the first surface. The switching device further includes an insulated gate electrode disposed on top of the second surface for controlling a source to drain current. The switching device further includes a source electrode interposed into the insulated gate electrode for substantially preventing a coupling of an electrical field between the gate electrode and an epitaxial region underneath the insulated gate electrode. The source electrode further covers and extends over the insulated gate for covering an area on the second surface of the semiconductor to contact the source region. The semiconductor substrate further includes an epitaxial layer disposed above and having a different dopant concentration than the drain region. The insulated gate electrode further includes an insulation layer for insulating the gate electrode from the source electrode wherein the insulation layer having a thickness depending on a Vgsmax rating of the vertical power device. | 06-17-2010 |
20100190307 | HIGH DENSITY TRENCH MOSFET WITH SINGLE MASK PRE-DEFINED GATE AND CONTACT TRENCHES - Trench gate MOSFET devices may be formed using a single mask to define gate trenches and body contact trenches. A hard mask is formed on a surface of a semiconductor substrate. A trench mask is applied on the hard mask to predefine a body contact trench and a gate trench. These predefined trenches are simultaneously etched into the substrate to a first predetermined depth. A gate trench mask is next applied on top of the hard mask. The gate trench mask covers the body contact trenches and has openings at the gate trenches that are wider than those trenches. The gate trench, but not the body contact trench, is etched to a second predetermined depth. Conductive material of a first kind may fill the gate trench to form a gate. Conductive material of a second kind may fill the body contact trench to form a body contact. | 07-29-2010 |
20100291744 | HIGH DENSITY TRENCH MOSFET WITH SINGLE MASK PRE-DEFINED GATE AND CONTACT TRENCHES - Trench gate MOSFET devices may be formed using a single mask to define gate trenches and body contact trenches. A hard mask is formed on a surface of a semiconductor substrate. A trench mask is applied on the hard mask to predefine a body contact trench and a gate trench. These predefined trenches are simultaneously etched into the substrate to a first predetermined depth. A gate trench mask is next applied on top of the hard mask. The gate trench mask covers the body contact trenches and has openings at the gate trenches. The gate trench, but not the body contact trench, is etched to a second predetermined depth. Conductive material of a first kind may fill the gate trench to form a gate. Conductive material of a second kind may fill the body contact trench to form a body contact. | 11-18-2010 |
20100302810 | VOLTAGE CONVERTERS WITH INTEGRATED LOW POWER LEAKER DEVICE AND ASSOCIATED METHODS - Voltage converters with integrated low power leaker device and associated methods are disclosed herein. In one embodiment, a voltage converter includes a switch configured to convert a first electrical signal into a second electrical signal different than the first electrical signal. The voltage converter also includes a controller operatively coupled to the switch and a leaker device electrically coupled to the controller. The controller is configured to control the on and off gates of the switch, and the leaker device is configured to deliver power to the controller. The leaker device and the switch are formed on a first semiconductor substrate, and the controller is formed on second semiconductor substrate separate from the first semiconductor substrate. | 12-02-2010 |
20110057259 | METHOD FOR FORMING A THICK BOTTOM OXIDE (TBO) IN A TRENCH MOSFET - A method for forming a thick bottom oxide in the bottom of a trench used in a vertical MOSFET. Initially, an n-type substrate has an n-type epitaxial layer grown thereon. A top portion of the n-type epitaxial layer is implanted with p-type dopants to provide a p-layer. A trench is then etched into the p- and n-type epitaxial layer. A high density plasma chemical vapor deposition (HDPCVD) process is used to either partially or fully fill the trench. Any oxide on the top surface of the p-layer is then removed, such as by using a chemical mechanical polishing step. Then, an isotropic etching step, such as a wet etch, is used to remove the silicon dioxide from the trench, while leaving a thick bottom oxide at the bottom of the trench. The HDPCVD process utilizes minimal thermal budget to form the thick bottom oxide. | 03-10-2011 |
20110198588 | Polysilicon control etch-back indicator - This invention discloses a semiconductor wafer for manufacturing electronic circuit thereon. The semiconductor substrate further includes an etch-back indicator that includes trenches of different sizes having polysilicon filled in the trenches and then completely removed from some of the trenches of greater planar trench dimensions and the polysilicon still remaining in a bottom portion in some of the trenches having smaller planar trench dimensions. | 08-18-2011 |
20110207276 | POWER MOS DEVICE FABRICATION - Fabricating a semiconductor device includes forming a hard mask on the substrate having a top substrate surface; forming a gate trench in the substrate, through the hard mask; depositing gate material in the gate trench; removing the hard mask to leave a gate structure; implanting a body region; implanting a source region; forming a source body contact trench having a trench wall and a trench bottom; and disposing an anti-punch through implant along at least a section of the trench wall but not along the trench bottom. | 08-25-2011 |
20110227147 | SUPER JUNCTION DEVICE WITH DEEP TRENCH AND IMPLANT - RESURF effect devices with both relatively deep trenches and relatively deep implants are described herein. Also, methods of fabricating such devices are described herein. A RESURF effect device may include alternating regions of first and second conductivity types where each of the second regions includes an implant region formed into a trench region of the second region. | 09-22-2011 |
20120001176 | ETCH DEPTH DETERMINATION STRUCTURE - A semiconductor device wafer includes a test structure. The test structure includes a layer of material having an angle-shaped test portion disposed on at least a portion of a surface of the semiconductor wafer. A ruler marking on the surface of the semiconductor wafer proximate the test portion is adapted to facilitate measurement of a change in length of the test portion. | 01-05-2012 |
20120098058 | Semiconductor Device and Associated Fabrication Method - A semiconductor device and a method for forming the semiconductor device wherein the semiconductor comprises: a trench MOSFET, formed on a semiconductor initial layer, comprising a well region, wherein the semiconductor initial layer has a first conductivity type and wherein the well region has a second conductivity type; an integrated Schottky diode next to the trench MOSFET, comprising a anode metal layer contacted to the semiconductor initial layer; a trench isolation structure, coupled between the trench MOSFET and integrated Schottky diode, configured to resist part of lateral diffusion from the well region; wherein the well region comprises an overgrowth part which laterally diffuses under the trench isolation structure and extends out of it. | 04-26-2012 |
20120104467 | SELF-ALIGNED CONTACT STRUCTURE TRENCH JFET - According to one embodiment, a self-aligned trench structure junction gate field-effect transistor (JFET) includes a silicon substrate, two or more trenches having a P-type polysilicon gate region near a bottom portion of the trench and an interlayer dielectric layer (ILDL) above the P-type polysilicon gate region, a channel region separating each trench including epitaxial silicon, an N+ source region above the channel region extending between a top of each trench, and a source metal above the N+ source region. In another embodiment, a self-aligned trench structure JFET includes a silicon substrate, two or more trenches having an N-type polysilicon gate region near a bottom portion of the trench and an ILDL above the N-type polysilicon gate region, a channel region separating each trench including epitaxial silicon, a P+ source region above the channel region extending between a top of each trench, and a source metal above the P+ source region. | 05-03-2012 |
20120161225 | INTEGRATED MOSFET DEVICES WITH SCHOTTKY DIODES AND ASSOCIATED METHODS OF MANUFACTURING - The present technology discloses a semiconductor die integrating a MOSFET device and a Schottky diode. The semiconductor die comprises a MOSFET area comprising the active region of MOSFET, a Schottky diode area comprising the active region of Schottky diode, and a termination area comprising termination structures. Wherein the Schottky diode area is placed between the MOSFET area and the termination area such that the Schottky diode area surrounds the MOSFET area. | 06-28-2012 |
20120193631 | POLYSILICON CONTROL ETCH BACK INDICATOR - This invention discloses a semiconductor wafer for manufacturing electronic circuit thereon. The semiconductor substrate further includes an etch-back indicator that includes trenches of different sizes having polysilicon filled in the trenches and then completely removed from some of the trenches of greater planar trench dimensions and the polysilicon still remaining in a bottom portion in some of the trenches having smaller planar trench dimensions. | 08-02-2012 |
20120280311 | TRENCH-GATE MOSFET DEVICE AND METHOD FOR MAKING THE SAME - The embodiments of the present disclosure disclose a trench-gate MOSFET device and the method for making the trench-gate MOSFET device. The trench-gate MOSFET device comprises a curving dopant profile formed between the body region and the epitaxial layer so that the portion of the body region under the source metal contact has a smaller vertical thickness than the other portion of the body region. The trench-gate MOSFET device in accordance with the embodiments of the present disclosure has improved UIS capability compared with the traditional trench-gate MOSFET device. | 11-08-2012 |
20120329225 | POWER MOS DEVICE FABRICATION - Fabricating a semiconductor device includes forming a mask on a substrate having a top substrate surface; forming a gate trench in the substrate, through the mask; depositing gate material in the gate trench; removing the mask to leave a gate structure; implanting a body region; implanting a source region; forming a source body contact trench having a trench wall and a trench bottom; forming a plug in the source body contact trench, wherein the plug extends below a bottom of the body region; and disposing conductive material in the source body contact trench, on top of the plug. | 12-27-2012 |
20130043534 | HIGH DENSITY LATERAL DMOS AND ASSOCIATED METHOD FOR MAKING - The present disclosure discloses a lateral DMOS with recessed source contact and method for making the same. The lateral DMOS comprises a recessed source contact which has a portion recessed into a source region to reach a body region of the lateral DMOS. The lateral DMOS according to various embodiments of the present invention may have greatly reduced size and may be cost saving for fabrication. | 02-21-2013 |
20130093001 | POWER MOSFET DEVICE STRUCTURE FOR HIGH FREQUENCY APPLICATIONS - This invention discloses a new switching device that includes a drain disposed on a first surface and a source region disposed near a second surface of a semiconductor opposite the first surface. An insulated gate electrode is disposed on top of the second surface for controlling a source to drain current and a source electrode is interposed into the insulated gate electrode for substantially preventing a coupling of an electrical field between the gate electrode and an epitaxial region underneath the insulated gate electrode. The source electrode further covers and extends over the insulated gate for covering an area on the second surface of the semiconductor to contact the source region, An epitaxial layer is disposed above and having a different dopant concentration than the drain region. The gate electrode is insulated from the source electrode by an insulation layer having a thickness depending on a Vgsmax rating of the vertical power device. | 04-18-2013 |
20130187160 | INTEGRATED FIELD EFFECT TRANSISTORS WITH HIGH VOLTAGE DRAIN SENSING - An integrated circuit includes a junction field effect transistor (JFET) and a power metal oxide semiconductor field effect transistor (MOSFET) on a same substrate. The integrated circuit includes a drain sense terminal for sensing the drain of the power MOSFET through the JFET. The JFET protects a controller or other electrical circuit coupled to the drain sense terminal from high voltage that may be present on the drain of the power MOSFET. The JFET and the power MOSFET share a same drift region, which includes an epitaxial layer formed on the substrate. The integrated circuit may be packaged in a four terminal small outline integrated circuit (SOIC) package. The integrated circuit may be employed in a variety of applications including as an ideal diode. | 07-25-2013 |
20130234245 | SEMICONDUCTOR DEVICE AND ASSOCIATED FABRICATION METHOD - A super junction structural semiconductor device with a substantially rectangle-shaped first region, and a second region surrounding the periphery of the first region; trench gate MOSFET units in the first region comprising a plurality of trench gate regions and a first plurality of pillars; a body region between the trench gate regions and the first plurality of pillars; a second plurality of pillars in the second region extending along a corresponding side of the first region comprising a plurality of lateral pillars and a plurality of longitudinal pillars, wherein in a corner part of the second region, ends of the plurality of lateral pillars and ends of the plurality of longitudinal pillars are stagger and separated apart from each other. | 09-12-2013 |
20130328122 | SPLIT TRENCH-GATE MOSFET WITH INTEGRATED SCHOTTKY DIODE - A split trench-gate MOSFET device and method for forming this device is disclosed. The device has a trench gate structure, comprising a shield electrode and two gate electrodes, wherein a substantial portion of shield electrode region is lower than the gate electrode region, and wherein a portion of the shield electrode region extends to the top surface between the two gate electrodes. The device further comprises a source metal layer, contacting to an initial layer, a well region, the shield electrode and a source region at the top surface, wherein the contact between the source metal layer and the initial layer forms a Schottky diode. | 12-12-2013 |
20140103416 | SEMICONDUCTOR DEVICE HAVING ESD PROTECTION STRUCTURE AND ASSOCIATED METHOD FOR MANUFACTURING - A semiconductor device having an ESD protection structure and a method for forming the semiconductor device. The semiconductor device further includes a semiconductor transistor formed in an active cell area of a substrate. The ESD protection structure is formed atop a termination area of the substrate and is of solid closed shape. The ESD protection structure includes a central doped zone of a first conductivity type and a plurality of second-conductivity-type doped zones and first-conductivity-type doped zones alternately disposed surrounding the central doped zone. The central doped zone occupies substantially the entire portion of the ESD protection structure that is overlapped by a gate metal pad, and is electrically coupled to the gate metal pad. The outmost first-conductivity-type doped zone is electrically coupled to a source metal. The ESD protection structure features a reduced resistance and an improved current uniformity and provides enhanced ESD protection to the transistor. | 04-17-2014 |
20140117415 | JUNCTION FIELD EFFECT TRANSISTORS AND ASSOCIATED FABRICATION METHODS - A JFET having a semiconductor substrate of a first doping type, an epitaxial layer of the first doping type located on the semiconductor substrate, a body region of a second doping type located in the epitaxial layer, a source region of the first doping type located in the epitaxial layer, a gate region of the second doping type located in the body region, and a shielding layer of the second doping type located in the epitaxial layer, wherein the semiconductor substrate is configured as a drain region, the shielding layer is in a conductive path formed between the source region and the drain region. | 05-01-2014 |
20140117416 | SEMICONDUCTOR DEVICE AND ASSOCIATED METHOD FOR MANUFACTURING - A semiconductor device having a trench-gate MOSFET and a vertical JFET formed in a semiconductor layer. In the semiconductor device, a gate region of the vertical JFET may be electrically coupled to a source region of the trench-gate MOSFET, and a drain region of the vertical JFET and a drain region of the trench-gate MOSFET may share a common region in the semiconductor layer. | 05-01-2014 |
20140159143 | SUPER JUNCTION SEMICONDUCTOR DEVICE AND ASSOCIATED FABRICATION METHOD - A semiconductor device with a substrate, an epitaxy layer formed on the substrate, a plurality of deep wells formed in the epitaxy layer, a plurality of trench gate MOSFET units each of which is formed in top of the epitaxy layer between two adjacent deep well, wherein a trench gate of the trench gate MOSFET unit is shallower than half of the distance between two adjacent deep wells, which may reduce the product of on-state resistance and the gate charge of the semiconductor device. | 06-12-2014 |
20140353748 | FIELD EFFECT TRANSISTOR, TERMINATION STRUCTURE AND ASSOCIATED METHOD FOR MANUFACTURING - A field effect transistor (“FET”), a termination structure and associated method for manufacturing. The FET has a plurality of active transistor cells and a termination structure. The termination structure for the FET includes a plurality of termination cells arranged substantially in parallel from an inner side toward an outer side of a termination area of the FET. Each of the termination cells comprises a termination trench lined with a termination insulation layer and filled with a termination conduction layer. The innermost termination cell is electrically coupled to gate regions of the active transistor cells while the rest of the termination cells are electrically floating. | 12-04-2014 |