Abstract: In one general aspect, an apparatus can include a plurality of trench metal-oxide-semiconductor field effect transistors (MOSFET) devices formed within an epitaxial layer of a substrate, and a gate-runner trench disposed around the plurality of trench MOSFET devices and disposed within the epitaxial layer. The apparatus can also include a floating-field implant defined by a well implant and disposed around the gate-runner trench.

Abstract: In one general aspect, an apparatus can include a plurality of trench metal-oxide-semiconductor field effect transistors (MOSFET) devices formed within an epitaxial layer of a substrate, and a gate-runner trench disposed around the plurality of trench MOSFET devices and disposed within the epitaxial layer. The apparatus can also include a floating-field implant defined by a well implant and disposed around the gate-runner trench.

Abstract: Various structures and methods for improving the performance of trench-shielded power semiconductor devices and the like are described. An exemplary device comprises a semiconductor region having a surface, a first area of the semiconductor region, a well region of a first conductivity type disposed in the semiconductor region and around the first area, and a plurality of trenches extending in a semiconductor region. Each trench haves a first end disposed in a first portion of the well region, a second end disposed in a second portion of the well region, and a middle portion between the first and second ends and disposed in the first area. Each trench further having opposing sidewalls lined with a dielectric layer, and a conductive electrode disposed on at least a portion of the dielectric layer.

Abstract: Semiconductor devices and methods for making such devices that are especially suited for high-frequency applications are described. The semiconductor devices combine a SIT (or a junction field-effect transistor [JFET]) architecture with a PN super-junction structure. The SIT architecture can be made using a trench formation containing a gate that is sandwiched between thick dielectric layers. While the gate is vertically sandwiched between the two isolating regions in the trench, it is also connected to a region of one conductivity type of the super-junction structure, thereby allowing control of the current path of the semiconductor device. Such semiconductor devices have a lower specific resistance and capacitance relative to conventional planar gate and recessed gate SIT semiconductor devices. Other embodiments are described.

Abstract: A method of forming a field effect transistor (FET) includes: forming a drift region comprising a stack of alternating conductivity type silicon layers; forming a drain region of a first conductivity type extending into the stack of alternating conductivity type silicon layers; forming a trench gate extending into the stack of alternating conductivity type silicon layers, the trench gate having a non-active sidewall and an active sidewall being perpendicular to one another; and forming a body region of a second conductivity type adjacent to the active sidewall of the trench gate, wherein the trench gate and the drain region are formed such that the non-active sidewall of the trench gate faces the drain region.

Abstract: A high voltage semiconductor device, such as a RESURF transistor, having improved properties, including reduced on state resistance. The device includes a semiconductor substrate with a drift region between source region and drain regions. The drift region includes a structure having a spaced trench capacitor extending between the source region and the drain region and a vertical stack extending between the source region and the drain region. When the device is in an on state, current flows between the source and drain regions; and, when the device is in an off/blocking state, the drift region is depleted into the stack.

Abstract: Semiconductor devices and methods for making such devices that are especially suited for high-frequency applications are described. The semiconductor devices combine a SIT (or a junction field-effect transistor [JFET]) architecture with a PN super-junction structure. The SIT architecture can be made using a trench formation containing a gate that is sandwiched between thick dielectric layers. While the gate is vertically sandwiched between the two isolating regions in the trench, it is also connected to a region of one conductivity type of the super-junction structure, thereby allowing control of the current path of the semiconductor device. Such semiconductor devices have a lower specific resistance and capacitance relative to conventional planar gate and recessed gate SIT semiconductor devices. Other embodiments are described.

Abstract: A method of forming a field effect transistor (FET) includes: forming a drift region comprising a stack of alternating conductivity type silicon layers; forming a drain region of a first conductivity type extending into the stack of alternating conductivity type silicon layers; forming a trench gate extending into the stack of alternating conductivity type silicon layers, the trench gate having a non-active sidewall and an active sidewall being perpendicular to one another; and forming a body region of a second conductivity type adjacent to the active sidewall of the trench gate, wherein the trench gate and the drain region are formed such that the non-active sidewall of the trench gate faces the drain region.

Abstract: A high voltage semiconductor device, such as a RESURF transistor, having improved properties, including reduced on state resistance. The device includes a semiconductor substrate with a drift region between source region and drain regions. The drift region includes a structure having a spaced trench capacitor extending between the source region and the drain region and a vertical stack extending between the source region and the drain region. When the device is in an on state, current flows between the source and drain regions; and, when the device is in an off/blocking state, the drift region is depleted into the stack.

Abstract: A field effect transistor includes a trench gate extending into a semiconductor region. The trench gate has a front wall facing a drain region and a side wall perpendicular to the front wall. A channel region extends along the side wall of the trench gate, and a drift region extends at least between the drain region and the trench gate. The drift region includes a stack of alternating conductivity type silicon layers.

Abstract: A high voltage semiconductor device, such as a RESURF transistor, having improved properties, including reduced on state resistance. The device includes a semiconductor substrate; a source region and a drain region provided in the substrate; wherein the source region and the drain region are laterally spaced from each other; and a drift region in the substrate between the source region and the drain region. The drift region includes a structure having at least two spaced trench capacitors extending between the source region and the drain region; and further includes a stack having at least a first region of a first conductivity type, a second region of a second conductivity type, and a third region of the first conductivity type, wherein the stack extends between the source region and the drain region and between the at least first and second trench capacitors and in electrical connection to the first and second trench capacitors.

Abstract: Various structures and methods for improving the performance of trench-shielded power semiconductor devices and the like are described.

Abstract: Devices, methods, and processes that improve immunity to transient voltages and reduce parasitic impedances. Immunity to unclamped inductive switching events is improved. For example, a trench-gated power MOSFET device having a SiGe source is provided, where the SiGe source reduces parasitic npn transistor gain by reducing hole current in the body or well region, thereby decreasing the likelihood of a latch-up condition. A body tie on this device can also be eliminated to reduce transistor cell size. A trench-gated power MOSFET device having a SiGe body or well region is also provided. A SiGe body reduces hole current when the body diode is turned on, thereby reducing reverse recovery power losses. Device characteristics are also improved. For example, parasitic gate impedance is reduced through the use of a poly SiGe gate, and channel resistance is reduced through the use of a SiGe layer near the device's gate.

Abstract: A high voltage semiconductor device, such as a RESURF transistor, having improved properties, including reduced on state resistance. The device includes a semiconductor substrate; a source region and a drain region provided in the substrate; wherein the source region and the drain region are laterally spaced from each other; and a drift region in the substrate between the source region and the drain region. The drift region includes a structure having at least two spaced trench capacitors extending between the source region and the drain region; and further includes a stack having at least a first region of a first conductivity type, a second region of a second conductivity type, and a third region of the first conductivity type, wherein the stack extends between the source region and the drain region and between the at least first and second trench capacitors and in electrical connection to the first and second trench capacitors.

Abstract: A field effect transistor includes a trench gate extending into a semiconductor region. The trench gate has a front wall facing a drain region and a side wall perpendicular to the front wall. A channel region extends along the side wall of the trench gate, and a drift region extends at least between the drain region and the trench gate. The drift region includes a stack of alternating conductivity type silicon layers.

Abstract: A field effect transistor is formed as follows. Trenches are formed in a semiconductor region of a first conductivity type. Each trench is partially filled with one or more materials. A dual-pass angled implant is carried out to implant dopants of a second conductivity type into the semiconductor region through an upper surface of the semiconductor region and through upper trench sidewalls not covered by the one or more material. A high temperature process is carried out to drive the implanted dopants deeper into the mesa region thereby forming body regions of the second conductivity type between adjacent trenches. Source regions of the first conductivity type are then formed in each body region.

Abstract: A field effect transistor is formed as follows. A trench is formed in a semiconductor region. A dielectric layer lining the trench sidewalls and bottom is formed. The trench is filled with a conductive material. The conductive material is recessed into the trench to thereby form a shield electrode in a bottom portion of the trench. The recessing of the conductive material includes isotropic etching of the conductive material. An inter-electrode dielectric (IED) is formed over the recessed shield electrode.

Abstract: A field effect transistor includes a body region of a first conductivity type over a semiconductor region of a second conductivity type. A gate trench extends through the body region and terminates within the semiconductor region. At least one conductive shield electrode is disposed in the gate trench. A gate electrode is disposed in the gate trench over but insulated from the at least one conductive shield electrode. A shield dielectric layer insulates the at lease one conductive shield electrode from the semiconductor region. A gate dielectric layer insulates the gate electrode from the body region. The shield dielectric layer is formed such that it flares out and extends directly under the body region.

Abstract: Various embodiments for improved power devices as well as their methods of manufacture, packaging and circuitry incorporating the same for use in a wide variety of power electronic applications are disclosed. One aspect of the invention combines a number of charge balancing techniques and other techniques for reducing parasitic capacitance to arrive at different embodiments for power devices with improved voltage performance, higher switching speed, and lower on-resistance. Another aspect of the invention provides improved termination structures for low, medium and high voltage devices. Improved methods of fabrication for power devices are provided according to other aspects of the invention. Improvements to specific processing steps, such as formation of trenches, formation of dielectric layers inside trenches, formation of mesa structures and processes for reducing substrate thickness, among others, are presented.

Abstract: Various embodiments for improved power devices as well as their methods of manufacture, packaging and circuitry incorporating the same for use in a wide variety of power electronic applications are disclosed. One aspect of the invention combines a number of charge balancing techniques and other techniques for reducing parasitic capacitance to arrive at different embodiments for power devices with improved voltage performance, higher switching speed, and lower on-resistance. Another aspect of the invention provides improved termination structures for low, medium and high voltage devices. Improved methods of fabrication for power devices are provided according to other aspects of the invention. Improvements to specific processing steps, such as formation of trenches, formation of dielectric layers inside trenches, formation of mesa structures and processes for reducing substrate thickness, among others, are presented.