Abstract: This disclosure relates to a semiconductor device, and associated method of manufacture. The semiconductor device includes, a MOSFET integrated with a p-n junction, the p-n junction arranged as a clamping diode across a source contact and a drain contact of the MOSFET. The MOSFET defines a first breakdown voltage, and the clamping diode defines a second breakdown voltage, and the first breakdown voltage is greater than the second breakdown voltage. A series resistance of the clamping diode includes a drift resistance and a clamping resistance, and the drift resistance is formed together with the clamping diode and the clamping resistance is formed independently from the clamping diode and configured to secure a uniform avalanche current.

Abstract: The present disclosure relates to a trench metal-oxide-semiconductor field-effect transistor, trench MOSFET, and to a method for manufacturing such transistors. In particular, the present disclosure relates to trench MOSFETs having deep trenches adjacent to the more shallow gate defining trench for obtaining a RESURF effect. According to the present disclosure, an ion implantation region of a charge type similar to that of the drift region is formed in the drift region. The ion implantation region extends below the deep trenches of the trench MOSFET and is vertically aligned with a base of the deep trenches.

Abstract: A semiconductor device and method of manufacturing thereof is provided, including one or more mutually separated trench structures and semiconductor devices in which a first polysilicon body and a second polysilicon body are provided in the trenches, and the first and second polysilicon bodies can be individually biased. The method according to the present disclosure includes the step of performing a wet oxidation for oxidizing the first polysilicon body and the exposed upper surface of the sidewall for forming, within the active area, a first part of a second dielectric layer and subsequently performing a dry oxidation for forming a remaining part of the second dielectric layer. A second polysilicon body is arranged next within the active area on the second dielectric layer in the trench so that the second polysilicon body is separated from the sidewall of the trench and from the first polysilicon body by the second dielectric layer.

Abstract: A packaged semiconductor device is provided, including a first semiconductor die on which a first electrical component is integrated that includes a first terminal at a first surface of the first die and a second terminal at a second surface of the first die, a second semiconductor die similar to the first die, with a first surface of the second die facing the first surface of the first die. A first conductive element on the second surface of the first side electrically connected to the second terminal of the first electrical component, a second conductive element is on the second surface of the second die electrically connected to the second terminal of the second electrical component, and a third conductive element between the first surfaces of the first and the second die. The first terminals of the first and second electrical components are electrically connected through the third conductive element.

Abstract: A trench-gate semiconductor device and a manufacturing method thereof is provided. The device is provided with each unit cell including a first trench, and a second trench extending from a bottom of the first trench. The device includes a gate oxide layer arranged on a first side wall of the first trench, a second oxide layer arranged on a second side wall and bottom of the second trench, a first polysilicon region arranged inside the first trench, separated from the first side wall by the gate oxide layer, forming a gate of the unit cell. The device includes a second polysilicon region arranged inside the second trench, separated from the second side wall and bottom of the second trench by the second oxide layer, forming a buried source of the unit cell, and a third oxide layer arranged in between the first polysilicon region and the second polysilicon region.

Abstract: A semiconductor device is provided, including a substrate having a first epitaxial layer arranged thereon and a voltage blocking element arranged in the first epitaxial layer, a second epitaxial layer arranged on the first epitaxial layer, and a vertical switching element arranged in the second epitaxial layer.

Abstract: The present disclosure relates to a semiconductor device, and associated method of manufacture. The semiconductor device includes, MOSFET integrated with a p-n junction, the p-n junction arranged as a clamping diode across a source contact and a drain contact of the MOSFET. The MOSFET defines a first breakdown voltage and the clamping diode defines a second breakdown voltage, with the first breakdown voltage being greater than the second breakdown voltage so that the clamp diode is configured and arranged to receive a low avalanche current and the MOSFET is configured and arranged to receive a high avalanche current.

Abstract: The present disclosure relates to a semiconductor device, and associated method of manufacture. The semiconductor device includes, MOSFET integrated with a p-n junction, the p-n junction arranged as a clamping diode across a source contact and a drain contact of the MOSFET. The MOSFET defines a first breakdown voltage and the clamping diode defines a second breakdown voltage, with the first breakdown voltage being greater than the second breakdown voltage so that the clamp diode is configured and arranged to receive a low avalanche current and the MOSFET is configured and arranged to receive a high avalanche current.

Abstract: A field effect transistor semiconductor device having a compact device footprint for use in automotive and hot swap applications. The device includes a plurality of field effect transistor cells with the plurality of transistor cells having at least one low threshold voltage transistor cell and at least one high threshold voltage transistor cell arranged on a substrate. The field effect transistor semiconductor device is configured and arranged to operate the at least one high threshold voltage transistor cell during linear mode operation, and operate both the low threshold voltage transistor cell and the high threshold voltage transistor cell during resistive mode operation. Further provided is a method of operating field effect transistor semiconductor device including a plurality of field effect transistor cells that includes at least one low threshold voltage transistor cell and at least one high threshold voltage transistor cell.

Abstract: A field effect transistor semiconductor device having a compact device footprint for use in automotive and hot swap applications. The device includes a plurality of field effect transistor cells with the plurality of transistor cells having at least one low threshold voltage transistor cell and at least one high threshold voltage transistor cell arranged on a substrate. The field effect transistor semiconductor device is configured and arranged to operate the at least one high threshold voltage transistor cell during linear mode operation, and operate both the low threshold voltage transistor cell and the high threshold voltage transistor cell during resistive mode operation. Further provided is a method of operating field effect transistor semiconductor device including a plurality of field effect transistor cells that includes at least one low threshold voltage transistor cell and at least one high threshold voltage transistor cell.

Abstract: A field effect transistor semiconductor device having a compact device footprint for use in automotive and hot swap applications. The device includes a plurality of field effect transistor cells with the plurality of transistor cells having at least one low threshold voltage transistor cell and at least one high threshold voltage transistor cell arranged on a substrate. The field effect transistor semiconductor device is configured and arranged to operate the at least one high threshold voltage transistor cell during linear mode operation, and operate both the low threshold voltage transistor cell and the high threshold voltage transistor cell during resistive mode operation. Further provided is a method of operating field effect transistor semiconductor device including a plurality of field effect transistor cells that includes at least one low threshold voltage transistor cell and at least one high threshold voltage transistor cell.

Abstract: A semiconductor uses an isolation trench, and one or more additional trenches to those required for isolation are provided. These additional trenches can be connected between a transistor gate and the drain to provide additional gate-drain capacitance, or else they can be used to form series impedance coupled to the transistor gate. These measures can be used separately or in combination to reduce the switching speed and thereby reduce current spikes.

Abstract: A trench-gate device with lateral RESURF pillars has an additional implant beneath the gate trench. The additional implant reduces the effective width of the semiconductor drift region between the RESURF pillars, and this provides additional gate shielding which improves the electrical characteristics of the device.

Abstract: A trench-gate semiconductor device is disclosed, in which the player (10,6) which forms the body region (in a n-channel device) extends adjacent the trench (4) deeper into the device, to lie adjacent a lower trench electrode (3b, 3c). Since the p-layer extension (6) forms part of the channel, it must be very low doped, in order not to increase unduly the channel resistance in the on-state. The replacement of some of the out-diffusion resistance in the drift region by the (smaller) channel resistance results in a lower over-all Rdson. In the off-state, the p-layer forms, together with the underlying n-drift layer, a non-abrupt function, so that the depletion region in the off-state extends closer to the top surface (2) than for a conventional RSO trench-MOS, being split between the p- and n-layers, rather than all being in the n-drift region.

Abstract: Consistent with an example embodiment, there is a package that includes a first voltage terminal, and a second voltage terminal, a first die including a first MOSFET having a drain region electrically connected to the first voltage terminal and further having a source region, A second die is adjacent to the first die, the second die includes a second MOSFET having a drain region electrically connected to the source region of the first MOSFET and having a source region electrically connected to the second voltage terminal. The semiconductor package further includes a vertical capacitor having a first plate electrically connected to the drain region of the first MOSFET and a second plate electrically connected to the source region of the second MOSFET and the second plate is electrically insulated from the first plate by a dielectric material. The capacitor is integrated on the first die or the second die.

Abstract: In an example embodiment, an integrated circuit (IC) comprises a substrate separating one of a source and drain from a semiconductor region. The IC comprises a vertical transistor including the source or drain. A gate electrode is formed in a trench extending into the semiconductor region; the gate electrode is electrically insulated from the semiconductor region by a dielectric lining in the trench and the other of said source or drain in the semiconducting region. An insulating trench terminates the vertical transistor; a vertical capacitor region (V-Cap) is adjacent to the vertical transistor; a first capacitor plate of the V-Cap comprises the source or drain separated from the semiconductor region by the substrate; the V-Cap further comprises at least one trench extending into the semiconductor region; the at least one trench comprises an electrically insulating liner material insulating a conductive material defining a second capacitor plate separated from the first capacitor plate.

Abstract: A trench-gate semiconductor device is disclosed, in which the p-layer (10,6) which forms the body region (in a n-channel device) extends adjacent the trench (4) deeper into the device, to lie adjacent a lower trench electrode (3b, 3c). Since the p-layer extension (6) forms part of the channel, it must be very low doped, in order not to increase unduly the channel resistance in the on-state. The re-placement of some of the out-diffusion resistance in the drift region by the (smaller) channel resistance results in a lower over-all Rdson. In the off-state, the p-layer forms, together with the underlying n-drift layer, a non-abrupt function, so that the depletion region in the off-state extends closer to the top surface (2) than for a conventional RSO trench-MOS, being split between the p- and n-layers, rather than all being in the n-drift region.