Patent application number | Description | Published |
20080246080 | Shallow trench isolation (STI) based laterally diffused metal oxide semiconductor (LDMOS) - An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device includes a first heavily doped region to represent a source region. A second heavily doped region represents a drain region of the semiconductor device. A third heavily doped region represents a gate region of the semiconductor device. The semiconductor device further includes a shallow trench isolation (STI) region to increase the resistance from the drain region to the source region. The STI region includes a first side vertically aligned with a second side of the gate region. The STI region extends from the first side to a second side in contact with a second side of the drain region. The breakdown voltage of the n-type semiconductor device is directly proportional to a vertical length, or a depth, of the first side and/or the second side of the STI region. The horizontal length, or distance from the first side to the second side, of the STI region does not substantially contribute to the breakdown voltage of the semiconductor device. As a result, a conventional CMOS logic foundry technology may fabricate the STI region of the semiconductor device using a low operating voltage process minimum design rule. | 10-09-2008 |
20090050971 | High voltage durability transistor and method for fabricating same - According to one exemplary embodiment, a method for fabricating a high voltage durability transistor comprises forming a gate over a gate oxide layer formed over a substrate, aligning an exposure mask with the gate, and selectively blocking exposure of the gate during gate implant doping, by exposure shields formed in the exposure mask, thereby producing the high voltage durability transistor. In one embodiment, an exemplary high voltage durability transistor comprises a gate formed over a gate oxide layer, the gate oxide layer being situated over a semiconductor substrate, where the gate has a reduced doping implant due to selective implant blocking provided by exposure shields formed in an exposure mask. The selective implant blocking results in an enhanced dielectric barrier so as to produce a high voltage durability transistor. The enhanced dielectric barrier has a depletion region with an increased thickness. | 02-26-2009 |
20100295125 | Split gate oxides for a laterally diffused metal oxide semiconductor (LDMOS) - An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device includes a first heavily doped region to represent a source region. A second heavily doped region represents a drain region of the semiconductor device. A third heavily doped region represents a gate region of the semiconductor device. The semiconductor device includes a gate oxide positioned between the source region and the drain region, below the gate region. The semiconductor device uses a split gate oxide architecture to form the gate oxide. The gate oxide includes a first gate oxide having a first thickness and a second gate oxide having a second thickness. | 11-25-2010 |
20100295126 | High dielectric constant gate oxides for a laterally diffused metal oxide semiconductor (LDMOS) - An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device includes a first heavily doped region to represent a source region. A second heavily doped region represents a drain region of the semiconductor device. A metal region represents a gate region of the semiconductor device. The semiconductor device includes a gate oxide positioned between the source region and the drain region, below the gate region. The semiconductor device uses a high dielectric constant (high-κ dielectric) material. | 11-25-2010 |
20100320561 | Method for forming a one-time programmable metal fuse and related structure - According to one exemplary embodiment, a method for forming a one-time programmable metal fuse structure includes forming a metal fuse structure over a substrate, the metal fuse structure including a gate metal segment situated between a dielectric segment and a polysilicon segment, a gate metal fuse being formed in a portion of the gate metal segment. The method further includes doping the polysilicon segment so as to form first and second doped polysilicon portions separated by an undoped polysilicon portion where, in one embodiment, the gate metal fuse is substantially co-extensive with the undoped polysilicon portion. The method can further include forming a first silicide segment on the first doped polysilicon portion and a second silicide segment on the second doped polysilicon portion, where the first and second silicide segments form respective terminals of the one-time programmable metal fuse structure. | 12-23-2010 |
20110031585 | Method for fabricating a MIM capacitor using gate metal for electrode and related structure - According to one exemplary embodiment, a method for fabricating a MIM capacitor in a semiconductor die includes forming a dielectric one segment over a substrate and a metal one segment over the dielectric one segment, where the metal one segment forms a lower electrode of the MIM capacitor. The method further includes forming a dielectric two segment over the dielectric one segment and a metal two segment over the dielectric two segment, where a portion of the metal two segment forms an upper electrode of the MIM capacitor. The metal one segment comprises a first gate metal. The metal two segment can comprise a second gate metal. | 02-10-2011 |
20110057271 | Semiconductor Device with Increased Breakdown Voltage - Optimization of the implantation structure of a metal oxide silicon field effect transistor (MOSFET) device fabricated using conventional complementary metal oxide silicon (CMOS) logic foundry technology to increase the breakdown voltage. The techniques used to optimize the implantation structure involve lightly implanting the gate region, displacing the drain region from the gate region, and implanting P-well and N-well regions adjacent to one another without an isolation region in between. | 03-10-2011 |
20110079917 | Interposer structure with passive component and method for fabricating same - According to an exemplary embodiment, an interposer structure for electrically coupling a semiconductor die to a support substrate in a semiconductor package includes at least one through-wafer via extending through a semiconductor substrate, where the at least one through-wafer via provides an electrical connection between the semiconductor die and the support substrate. The interposer structure further includes a passive component including a trench conductor, where the trench conductor extends through the semiconductor substrate. The passive component further includes a dielectric liner situated between the trench conductor and the semiconductor substrate. The passive component can further include at least one conductive pad for electrically coupling the trench conductor to the semiconductor die. The passive component can be, for example, an inductor or an antenna. | 04-07-2011 |
20110169077 | Semiconductor device having a modified shallow trench isolation (STI) region and a modified well region - An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device includes a modified breakdown shallow trench isolation (STI) region to effectively reduce a drain to source resistance when compared to a conventional semiconductor device, thereby increasing the breakdown voltage of the semiconductor device when compared to the conventional semiconductor device. The modified breakdown STI region allows more current to pass from a source region to a drain region of the semiconductor device, thereby further increasing the break down voltage of the semiconductor device from that of the conventional semiconductor device. The semiconductor device may include a modified well region to further reduce the drain to source resistance of the semiconductor device. The modified breakdown STI region allows even more current to pass from a source region to a drain region of the semiconductor device, thereby further increasing the break down voltage of the semiconductor device from that of the conventional semiconductor device. | 07-14-2011 |
20110169079 | Semiconductor device having an overlapping multi-well implant and method for fabricating same - According to one embodiment, a semiconductor device having an overlapping multi-well implant comprises an isolation structure formed in a semiconductor body, a first well implant formed in the semiconductor body surrounding the isolation structure, and a second well implant overlapping at least a portion of the first well implant. The disclosed semiconductor device, which may be an NMOS or PMOS device, can further comprise a gate formed over the semiconductor body adjacent to the isolation structure, wherein the first well implant extends a first lateral distance under the gate and the second well implant extends a second lateral distance under the gate, and wherein the first and second lateral distances may be different. In one embodiment, the disclosed semiconductor device is fabricated as part of an integrated circuit including a power management circuit or a power amplifier. | 07-14-2011 |
20110186926 | Semiconductor device having a lightly doped semiconductor gate and method for fabricating same - According to one embodiment, a semiconductor device comprises a high-k gate dielectric overlying a well region having a first conductivity type formed in a semiconductor body, and a semiconductor gate formed on the high-k gate dielectric. The semiconductor gate is lightly doped so as to have a second conductivity type opposite the first conductivity type. The disclosed semiconductor device, which may be an NMOS or PMOS device, can further comprise an isolation region formed in the semiconductor body between the semiconductor gate and a drain of the second conductivity type, and a drain extension well of the second conductivity type surrounding the isolation region in the semiconductor body. In one embodiment, the disclosed semiconductor device is fabricated as part of an integrated circuit including one or more CMOS logic devices. | 08-04-2011 |
20110186934 | Low mismatch semiconductor device and method for fabricating same - Disclosed is a low mismatch semiconductor device that comprises a lightly doped channel region having a first conductivity type and a first dopant concentration in a semiconductor body, and a high-k metal gate stack including a gate metal layer formed over a high-k gate dielectric without having a dielectric cap on the high-k dielectric. The high-k metal gate stack being formed over the lightly doped channel region. The lightly doped channel region may be a P- or N-conductivity region, for example, and may be part of a corresponding P- or N-semiconductor substrate, or a P- or N-well formed in a substrate of the respectively opposite conductivity type. The disclosed semiconductor device, which may be an NMOS or PMOS analog device, for example, can be fabricated as part of an integrated circuit including one or more CMOS logic devices. | 08-04-2011 |
20110210388 | Integrated native device without a halo implanted channel region and method for its fabrication - According to one embodiment, a semiconductor structure including an integrated native device without a halo implanted channel region comprises an arrangement of semiconductor devices formed over a common substrate, the arrangement includes native devices disposed substantially perpendicular to non-native devices, wherein each of the native and non-native devices includes a respective channel region. The arrangement is configured to prevent formation of halo implants in the native device channel regions during halo implantation of the non-native device channel regions. In one embodiment, the disclosed native devices comprise native transistors capable of avoiding threshold voltage roll-up for channel lengths less than approximately 0.5 um. | 09-01-2011 |
20110303978 | Semiconductor Device Having an Enhanced Well Region - An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device includes an enhanced well region to effectively increase a voltage at which punch-through occurs when compared to a conventional semiconductor device. The enhanced well region includes a greater number of excess carriers when compared to a well region of the conventional semiconductor device. These larger number of excess carriers attract more carriers allowing more current to flow through a channel region of the semiconductor device before depleting the enhanced well region of the carriers. As a result, the semiconductor device may accommodate a greater voltage being applied to its drain region before the depletion region of the enhanced well region and a depletion region of a well region surrounding the drain region merge into a single depletion region. | 12-15-2011 |
20120091525 | Split Gate Oxides for a Laterally Diffused Metal Oxide Semiconductor (LDMOS) - An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device includes a first heavily doped region to represent a source region. A second heavily doped region represents a drain region of the semiconductor device. A third heavily doped region represents a gate region of the semiconductor device. The semiconductor device includes a gate oxide positioned between the source region and the drain region, below the gate region. The semiconductor device uses a split gate oxide architecture to form the gate oxide. The gate oxide includes a first gate oxide having a first thickness and a second gate oxide having a second thickness. | 04-19-2012 |
20120161233 | Reduction of Parasitic Capacitance in a Semiconductor Device - An apparatus is disclosed to increase a reduced a parasitic capacitance of a semiconductor device. The semiconductor device includes a modified gate region to effectively reduce an overlap capacitance and modified well regions to effectively reduce a junction capacitance. The modified gate region includes a doped region and an undoped to decrease an effective area of the overlap capacitance. The modified well regions are separated by a substantially horizontal distance to increase an effective distance of the junction capacitance. This decrease in the effective area of the overlap capacitance and this increase in the effective distance of the junction capacitance reduces the parasitic capacitance of the semiconductor device. | 06-28-2012 |
20120217613 | Programmable Fuse - According to one exemplary embodiment, a method for forming a one-time programmable metal fuse structure includes forming a metal fuse structure over a substrate, the metal fuse structure including a gate metal segment situated between a dielectric segment and a polysilicon segment, a gate metal fuse being formed in a portion of the gate metal segment. The method further includes doping the polysilicon segment so as to form first and second doped polysilicon portions separated by an undoped polysilicon portion where, in one embodiment, the gate metal fuse is substantially co-extensive with the undoped polysilicon portion. The method can further include forming a first silicide segment on the first doped polysilicon portion and a second silicide segment on the second doped polysilicon portion, where the first and second silicide segments form respective terminals of the one-time programmable metal fuse structure. | 08-30-2012 |
20120313166 | Semiconductor Device Having A Modified Shallow Trench Isolation (STI) Region And A Modified Well Region - An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device can include a modified breakdown shallow trench isolation (STI) region to effectively reduce its drain to source resistance when compared to a conventional semiconductor device. This reduction in the drain to source resistance increases the breakdown voltage of the semiconductor device when compared to the conventional semiconductor device by allowing more current to pass from a source region to a drain region of the semiconductor device. The semiconductor device can include a modified well region to reduce its drain to source resistance. The modified well region allows more current to pass from a source region to a drain region of the semiconductor device, thereby further increasing the break down voltage of the semiconductor device from that of the conventional semiconductor device. | 12-13-2012 |
20120329221 | Semiconductor Device Having an Enhanced Well Region - An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device includes an enhanced well region to effectively increase a voltage at which punch-through occurs when compared to a conventional semiconductor device. The enhanced well region includes a greater number of excess carriers when compared to a well region of the conventional semiconductor device. These larger number of excess carriers attract more carriers allowing more current to flow through a channel region of the semiconductor device before depleting the enhanced well region of the carriers. As a result, the semiconductor device may accommodate a greater voltage being applied to its drain region before the depletion region of the enhanced well region and a depletion region of a well region surrounding the drain region merge into a single depletion region. | 12-27-2012 |
20130001574 | FIELD TRANSISTOR STRUCTURE MANUFACTURED USING GATE LAST PROCESS - According to embodiments of the invention, a field transistor structure is provided. The field transistor structure includes a semiconductor substrate, a metal gate, a polycrystalline silicon (polysilicon) layer, and first and second metal portions. The polysilicon layer has first, second, third, and fourth sides and is disposed between the semiconductor substrate on the first side and the metal gate on the second side. The polysilicon layer is also disposed between the first and second metal portions on the third and fourth sides. According to some embodiments of the present invention, the field transistor structure may also include a thin metal layer disposed between the polysilicon layer and the semiconductor substrate. The thin metal layer may be electronically coupled to each of the first and second metal portions. | 01-03-2013 |
20130082325 | One-Time Programmable Device Having an LDMOS Structure and Related Method - According to one embodiment, a one-time programmable (OTP) device having a lateral diffused metal-oxide-semiconductor (LDMOS) structure comprises a pass gate including a pass gate electrode and a pass gate dielectric, and a programming gate including a programming gate electrode and a programming gate dielectric. The programming gate is spaced from the pass gate by a drain extension region of the LDMOS structure. The LDMOS structure provides protection for the pass gate when a programming voltage for rupturing the programming gate dielectric is applied to the programming gate electrode. A method for producing such an OTP device comprises forming a drain extension region, fabricating a pass gate over a first portion of the drain extension region, and fabricating a programming gate over a second portion of the drain extension region. | 04-04-2013 |
20130113077 | Metal Finger Capacitor for High-K Metal Gate Processes - Embodiments described herein provide a structure for finger capacitors, and more specifically metal-oxide-metal (“MOM”) finger capacitors and arrays of finger capacitors. A plurality of Shallow Trench Isolation (STI) formations is associated with every other column of capacitor fingers, with poly fill formations covering the STI formations to provide a more robust and efficient structure. | 05-09-2013 |
20130175613 | Semiconductor Device with a Lightly Doped Gate - According to one embodiment, a semiconductor device comprises a high-k gate dielectric overlying a well region having a first conductivity type formed in a semiconductor body, and a semiconductor gate formed on the high-k gate dielectric. The semiconductor gate is lightly doped so as to have a second conductivity type opposite the first conductivity type. The disclosed semiconductor device, which may be an NMOS or PMOS device, can further comprise an isolation region formed in the semiconductor body between the semiconductor gate and a drain of the second conductivity type, and a drain extension well of the second conductivity type surrounding the isolation region in the semiconductor body. In one embodiment, the disclosed semiconductor device is fabricated as part of an integrated circuit including one or more CMOS logic devices. | 07-11-2013 |
20130214353 | Field Effect Transistor Having Multiple Effective Oxide Thicknesses and Corresponding Multiple Channel Doping Profiles - A FET includes a gate dielectric structure associated with a single gate electrode, the gate dielectric structure having at least two regions, each of those regions having a different effective oxide thickness, the FET further having a channel region with at least two portions each having a different doping profile. A semiconductor manufacturing process produces a FET including a gate dielectric structure associated with a single gate electrode, the gate dielectric structure having at least two regions, each of those regions having a different effective oxide thickness, the FET further having a channel region with at least two portions each having a different doping profile. | 08-22-2013 |
20130270636 | Transistor Having An Isolated Body For High Voltage Operation - The present application discloses various implementations of a transistor having an isolated body for high voltage operation. In one exemplary implementation, such a transistor comprises a deep well implant having a first conductivity type disposed in a substrate having a second conductivity type opposite the first conductivity type. The transistor includes a source-side well and a drain-side well of the first conductivity type. The source-side well and the drain-side well are electrically coupled to the deep well implant. The deep well implant, the source-side well, and the drain-side well electrically isolate a body of the transistor from the substrate. | 10-17-2013 |
20130299904 | LDMOS One-Time Programmable Device - According to one embodiment, a one-time programmable (OTP) device having a lateral diffused metal-oxide-semiconductor (LDMOS) structure comprises a pass gate including a pass gate electrode and a pass gate dielectric, and a programming gate including a programming gate electrode and a programming gate dielectric. The programming gate is spaced from the pass gate by a drain extension region of the LDMOS structure. The LDMOS structure provides protection for the pass gate when a programming voltage for rupturing the programming gate dielectric is applied to the programming gate electrode. A method for producing such an OTP device comprises forming a drain extension region, fabricating a pass gate over a first portion of the drain extension region, and fabricating a programming gate over a second portion of the drain extension region. | 11-14-2013 |
20130302960 | One-Time Programmable Device - According to one embodiment, a one-time programmable (OTP) device having a lateral diffused metal-oxide-semiconductor (LDMOS) structure comprises a pass gate including a pass gate electrode and a pass gate dielectric, and a programming gate including a programming gate electrode and a programming gate dielectric. The programming gate is spaced from the pass gate by a drain extension region of the LDMOS structure. The LDMOS structure provides protection for the pass gate when a programming voltage for rupturing the programming gate dielectric is applied to the programming gate electrode. A method for producing such an OTP device comprises forming a drain extension region, fabricating a pass gate over a first portion of the drain extension region, and fabricating a programming gate over a second portion of the drain extension region. | 11-14-2013 |
20130342955 | Metal-Oxide-Metal Capacitor - A semiconductor structure may implement a metal-oxide-metal capacitor. When layer design rules change from one layer to the next, the structure may change the direction of the interleaved plates of the capacitor. For example, when the metallization width or spacing design rules change from layer M3 to layer M4, the structure may run the capacitor traces in different directions (e.g., orthogonal to one another) on M3 as compared to M4. Among the layers that adhere to the same design rules, for example layers M1, M2, and M3, the structure may run the capacitor traces in the same direction in each of the layers M1, M2, and M3. In this way, the capacitor traces overlap to large extent without misalignment on layers that have the same design rules, and the structure avoids misalignment of the capacitor traces when the design rules change. | 12-26-2013 |
20140021543 | LOW THRESHOLD VOLTAGE METAL OXIDE SEMICONDUCTOR - A semiconductor device includes a source region disposed with a semiconductor substrate; a drain region disposed with the semiconductor substrate; a gate region disposed onto the semiconductor substrate and positioned between the source region and the drain region. The semiconductor device also includes a gate oxide region disposed onto the semiconductor substrate in contact with the gate region and a well region implanted onto the semiconductor substrate and under the gate region and the gate oxide region. The gate oxide region has a lower outer edge portion that contacts the well region. | 01-23-2014 |
20140084368 | Semiconductor Device with Increased Breakdown Voltage - Optimization of the implantation structure of a metal oxide silicon field effect transistor (MOSFET) device fabricated using conventional complementary metal oxide silicon (CMOS) logic foundry technology to increase the breakdown voltage. The techniques used to optimize the implantation structure involve lightly implanting the gate region, displacing the drain region from the gate region, and implanting P-well and N-well regions adjacent to one another without an isolation region in between. | 03-27-2014 |
20140167173 | INCREASING THE BREAKDOWN VOLTAGE OF A METAL OXIDE SEMICONDUCTOR DEVICE - A semiconductor device includes a first well, a second well, and a separator structure. The first well and the second well are implanted in the semiconductor substrate. The separator structure is also implanted in the semiconductor substrate and separates the first well and the second well so that the first well and the second well do not contact each other. | 06-19-2014 |
20140183628 | METAL OXIDE SEMICONDUCTOR DEVICES AND FABRICATION METHODS - A semiconductor device includes a first well and a second well implanted in a semiconductor substrate. The semiconductor device further includes a raised drain structure above and in contact with the second well and separate from the gate structure. The raised drain structure includes a drain connection point above the surface of the second well. | 07-03-2014 |
20140191315 | MULTIGATE METAL OXIDE SEMICONDUCTOR DEVICES AND FABRICATION METHODS - A semiconductor device includes a first well and a second well implanted in a semiconductor substrate. The semiconductor device further includes a gate structure above the first and second wells between a raised source structure and a raised drain structure. The raised source structure above is in contact with the first well and connected with the gate structure through a first semiconductor fin structure. The raised drain structure above and in contact with the second well and connected with a second semiconductor fin structure. The second semiconductor fin structure includes at least a gap and a lightly doped portion. | 07-10-2014 |
20140197497 | NATIVE PMOS DEVICE WITH LOW THRESHOLD VOLTAGE AND HIGH DRIVE CURRENT AND METHOD OF FABRICATING THE SAME - A native p-type metal oxide semiconductor (PMOS) device that exhibits a low threshold voltage and a high drive current over a varying range of short channel lengths and a method for fabricating the same is discussed in the present disclosure. The source and drain regions of the native PMOS device, each include a strained region, a heavily doped raised region, and a lightly doped region. The gate region includes a stacked layer of a gate oxide having a high-k dielectric material, a metal, and a contact metal. The high drive current of the native PMOS device is primarily influenced by the increased carrier mobility due to the strained regions, the lower drain resistance due to the raised regions, and the higher gate capacitance due to the high-k gate oxide of the native PMOS device. | 07-17-2014 |
20140239451 | Semiconductor Devices Including A Lateral Bipolar Structure And Fabrication Methods - A semiconductor device includes an emitter region, a collector region and a base region. The emitter region is implanted in a semiconductor substrate. The collector region is implanted in the semiconductor substrate. The base region is disposed between the emitter region and collector region. The base region includes no more than one LDD region and no more than one halo region. The base region contacts directly with at least one of the emitter region and the collector region. | 08-28-2014 |
20140299964 | ON-CHIP INDUCTOR USING REDISTRIBUTION LAYER AND DUAL-LAYER PASSIVIATION - A system and method utilize a redistribution layer in a flip-chip or wirebond package, which is also used to route signals to bumps, as a layer for the construction of an on-chip inductor or a layer of a multiple-layer on-chip inductor. In one example, the redistribution layer is surrounded by dual-layer passivation to protect it, and the inductor formed thereby, from the environment and isolate it, and the inductor formed thereby, from the metal layer beneath it. | 10-09-2014 |
20140312396 | SPLIT MULTI-GATE FIELD-EFFECT TRANSISTOR - A semiconductor device based on split multi-gate field-effect transistor radio frequency devices is provided. The semiconductor device includes a substrate and a gate structure above the substrate and orthogonal to a channel axis. The semiconductor device also includes a semiconductor fin structure above the substrate along the channel axis. The semiconductor also includes a gate oxide region beneath the gate structure and in contact with the gate structure and the semiconductor fin structure. The gate oxide region has a first region with a first thickness and a first length. The gate oxide region also has a second region with a second thickness and a second length. The first thickness is greater than the second thickness. The first region and the second region are formed side-by-side along the channel axis. | 10-23-2014 |
20150076610 | Field Effect Transistor Structure Having One or More Fins - A field effect transistor (FET) having one or more fins provides an extended current path as compared to conventional finFETs. A raised source terminal is disposed on a fin adjacent to a sidewall spacer of a gate structure. The drain terminal and a first portion of the gate structure overlie a first well of a first conductivity type. A raised drain terminal is disposed such that it is spaced apart from the gate structure sidewalls. In some embodiments the drain terminal is disposed on a second, separate fin. the drain terminal and a second portion of the gate structure overlie a second well of a second conductivity type. | 03-19-2015 |