Abstract: The present invention relates i.a. to an H52 IBV (infectious bronchitis virus) encoding for a heterologous S (spike) protein or fragment thereof. Further, the present invention relates to an immunogenic composition comprising said H52 IBV encoding for a heterologous S (spike) protein or fragment thereof. Furthermore, the present invention relates to methods for immunizing a subject comprising administering to such subject the immunogenic composition of the present invention. Moreover, the present invention relates to methods of treating or preventing clinical signs caused by IBV in a subject of need, the method comprising administering to the subject a therapeutically effective amount of an immunogenic composition according to the present invention.

Abstract: A power semiconductor device includes a semiconductor body coupled to first and second load terminal structures, and first and second cells each configured for controlling a load current and electrically connected to the first load terminal structure and to a drift region. A first mesa in the first cell includes a port region electrically connected to the first load terminal structure, and a first channel region coupled to the drift region. A second mesa included in the second cell includes a port region electrically connected to the first load terminal structure, and a second channel region coupled to the drift region. The mesas are spatially confined in a direction perpendicular to a direction of the load current by an insulation structure, and have a total extension of less than 100 nm in that direction. The first channel region includes an inversion channel. The second channel region includes an accumulation channel.

Abstract: A gate driver integrated circuit (IC) and a method of operating the same is provided. The gate driver IC is configured to drive a transistor between switching states in a power circuit, and includes a memory configured to store at least one measurement window parameter that defines a measurement interval; measurement circuitry configured to measure, over the measurement interval, a value corresponding to an operation of the power circuit, the measured value being proportional to an input capacitance of the transistor; processing circuitry configured to determine a correction factor based on the measured value, the correction factor being proportional to the input capacitance of the transistor; and a gate controller configured to control a gate current of the transistor based on the switching states and the correction factor.

Abstract: A transistor device includes a first silicon nanowire array-MOSFET and a second silicon nanowire array-MOSFET integrated with a bulk drift region. The first silicon nanowire array-MOSFET is configured as an n-MOSFET by substantially only accommodating an electron current, and the second silicon nanowire array-MOSFET is configured as a p-MOSFET by substantially only accommodating a hole electron current. A current strength of a current through the first silicon nanowire array-MOSFET caused by electrons is at least 10 times larger than a current through the first silicon nanowire array-MOSFET caused by holes in an on-state of the transistor device. Further embodiments of transistor devices are described.

Abstract: A power semiconductor device includes a semiconductor body coupled to first and second load terminal structures, first and second cells electrically connected to the first load terminal structure and to a drift region, the drift region having a first conductivity type; a first mesa in the first cell and including: a port region electrically connected to the first load terminal structure, and a channel region coupled to the drift region; a second mesa in the second cell and including: a port region of the opposite conductivity type and electrically connected to the first load terminal structure, and a channel region coupled to the drift region. Each mesa is spatially confined, in a direction perpendicular to a direction of the load current within the respective mesa, by an insulation structure. The insulation structure houses a control electrode structure, and a guidance electrode arranged between the mesas.

Abstract: A power semiconductor transistor includes: a semiconductor body coupled to a load terminal; a drift region in the semiconductor body and having dopants of a first conductivity type; a first trench extending into the semiconductor body along a vertical direction and including a control electrode electrically insulated from the semiconductor body by an insulator; a second trench extending into the semiconductor body along the vertical direction; a mesa region arranged between the trenches and including a source region electrically connected to the load terminal and a channel region separating the source and drift regions; and a portion of a contiguous plateau region of a second conductivity type arranged in the semiconductor drift region and extending below the trenches and below the channel and source regions, the contiguous plateau region having a plurality of openings aligned below the channel region in a widthwise direction of the channel region.

Abstract: A power semiconductor device includes a semiconductor body coupled to first and second load terminal structures, an active cell field in the body, and a plurality of first and second cells in the active cell field. Each cell is electrically connected to the first load terminal structure and to a drift region. Each first cell includes a mesa having a port region electrically connected to the first load terminal structure, and a channel region coupled to the drift region. Each second cell includes a mesa having a port region of the opposite conductivity type electrically connected to the first load terminal structure, and a channel region coupled to the drift region. Each mesa is spatially confined in a direction perpendicular to a direction of the load current within the respective mesa, by an insulation structure and has a total extension of less than 100 nm in the direction.

Abstract: A power semiconductor device includes a semiconductor body coupled to first and second load terminal structures, and first and second cells each configured for controlling a load current and electrically connected to the first load terminal structure and to a drift region. A first mesa in the first cell includes a port region electrically connected to the first load terminal structure, and a first channel region coupled to the drift region. A second mesa included in the second cell includes a port region electrically connected to the first load terminal structure, and a second channel region coupled to the drift region. The mesas are spatially confined in a direction perpendicular to a direction of the load current by an insulation structure, and have a total extension of less than 100 nm in that direction. The first channel region includes an inversion channel. The second channel region includes an accumulation channel.

Abstract: A transistor device includes a first silicon nanowire array-MOSFET and a second silicon nanowire array-MOSFET integrated with a bulk drift region. The first silicon nanowire array-MOSFET is configured as an n-MOSFET by substantially only accommodating an electron current, and the second silicon nanowire array-MOSFET is configured as a p-MOSFET by substantially only accommodating a hole electron current. A current strength of a current through the first silicon nanowire array-MOSFET caused by electrons is at least 10 times larger than a current through the first silicon nanowire array-MOSFET caused by holes in an on-state of the transistor device. Further embodiments of transistor devices are described.

Abstract: A power semiconductor device is disclosed. The device includes a semiconductor body coupled to a first load terminal structure and a second load terminal structure, a first cell and a second cell. A first mesa is included in the first cell, the first mesa including: a first port region and a first channel region. A second mesa included in the second cell, the second mesa including a second port region. A third cell is electrically connected to the second load terminal structure and electrically connected to a drift region. The third cell includes a third mesa comprising: a third port region, a third channel region, and a third control electrode.

Abstract: A power semiconductor device having an IGBT-configuration includes at least one power cell. Each power cell includes at least three trenches arranged laterally adjacent to each other. Each trench extends into a semiconductor body along a vertical direction and includes an insulator that insulates a respective electrode from the semiconductor body. The at least three trenches include at least one control trench whose electrode is electrically coupled to a control terminal, and a source trench whose electrode is electrically coupled to a first load terminal. An active mesa for conduction of at least a part of the load current is laterally confined at least by one of the at least one control trench and includes at least a respective section of each of a source region and a channel region. An auxiliary mesa is laterally confined by the source trench and one of the at least one control trench.

Abstract: A power semiconductor device includes a semiconductor body coupled to first and second load terminal structures, an active cell field in the body, and a plurality of first and second cells in the active cell field. Each cell is electrically connected to the first load terminal structure and to a drift region. Each first cell includes a mesa having a port region electrically connected to the first load terminal structure, and a channel region coupled to the drift region. Each second cell includes a mesa having a port region of the opposite conductivity type electrically connected to the first load terminal structure, and a channel region coupled to the drift region. Each mesa is spatially confined in a direction perpendicular to a direction of the load current within the respective mesa, by an insulation structure and has a total extension of less than 100 nm in the direction.

Abstract: A semiconductor device includes a transistor. The transistor includes a drift region of a first conductivity type in a semiconductor substrate having a first main surface, a body region of a second conductivity type between the drift region and the first main surface, and a plurality of trenches in the first main surface and patterning the semiconductor substrate into a plurality of mesas including a first mesa and a dummy mesa. The plurality of trenches includes at least one active trench. The first mesa is arranged at a first side of the active trench, and the dummy mesa is arranged at a second side of the active trench. A gate electrode is arranged in the active trench, and a source region of the first conductivity type is in the first mesa. A one-sided channel of the transistor is configured to be formed in the first mesa.

Abstract: A power semiconductor device has a semiconductor body coupled to first and second load terminal structures, the semiconductor body configured to conduct a load current during a conducting state of the device and having a drift region. The power semiconductor device includes a plurality of cells, each cell having: a first mesa in a first cell portion, the first mesa including: a first port region, and a first channel region, the first mesa exhibiting a total extension of less than 100 nm in a lateral direction, and a second mesa in a second cell portion including: a second port region, and a second channel region. A trench structure includes a control electrode structure configured to control the load current by inversion or accumulation. A guidance zone of the second conductivity type is below the second channel region and is displaced from the first and the second channel regions.

Abstract: A power semiconductor transistor includes a trench extending into a semiconductor body along a vertical direction and having first and second trench sidewalls and a trench bottom, an electrode in the trench electrically insulated from the semiconductor body, drift and source regions of a first conductivity type, a semiconductor channel region of a second conductivity type laterally adjacent the first trench sidewall and separating the source and drift regions, and a guidance zone. The guidance zone includes a bar section of the second conductivity type extending along the second trench sidewall or along a sidewall of another trench in the vertical direction to a depth in the semiconductor body deeper than the trench bottom, and a plateau section of the second conductivity type adjoining the bar section and extending under the trench bottom towards the semiconductor channel region. The plateau section has at least one opening below the channel region.

Abstract: An embodiment relates to a method of manufacturing an insulated gate bipolar transistor in a semiconductor body. A first field stop zone portion of a first conductivity type is formed on a semiconductor substrate. A second field stop zone portion of the first conductivity type is formed on the first field stop zone portion. A drift zone of the first conductivity type is formed on the second field stop zone portion. A doping concentration in the drift zone is smaller than 1013 cm?3 along a vertical extension of more than 30% of a thickness of the semiconductor body upon completion of the insulated gate bipolar transistor.

Abstract: A power semiconductor device includes an active cell region with a drift region, and IGBT cells at least partially arranged within the active cell region. Each IGBT cell includes at least one trench extending into the drift region along a vertical direction, an edge termination region surrounding the active cell region, and a transition region arranged between the active cell region and the edge termination region. The transition region has a width along a lateral direction from the active cell region towards the edge termination region. At least some of the IGBT cells are arranged within, or, respectively, extend into the transition region. An electrically floating barrier region of each IGBT cell is arranged within the active cell region and in contact with at least some of the trenches of the IGBT cells. The electrically floating barrier region does not extend into the transition region.

Abstract: A power semiconductor device is disclosed. The device includes a semiconductor body coupled to a first load terminal structure and a second load terminal structure, a first cell and a second cell. A first mesa is included in the first cell, the first mesa including: a first port region and a first channel region. A second mesa included in the second cell, the second mesa including a second port region. A third cell is electrically connected to the second load terminal structure and electrically connected to a drift region. The third cell includes a third mesa comprising: a third port region, a third channel region, and a third control electrode.

Abstract: A power semiconductor device includes a semiconductor body coupled to first and second load terminal structures, first and second cells electrically connected to the first load terminal structure and to a drift region, the drift region having a first conductivity type; a first mesa in the first cell and including: a port region electrically connected to the first load terminal structure, and a channel region coupled to the drift region; a second mesa in the second cell and including: a port region of the opposite conductivity type and electrically connected to the first load terminal structure, and a channel region coupled to the drift region. Each mesa is spatially confined, in a direction perpendicular to a direction of the load current within the respective mesa, by an insulation structure. The insulation structure houses a control electrode structure, and a guidance electrode arranged between the mesas.

Abstract: A power semiconductor device includes a semiconductor body coupled to first and second load terminal structures, and first and second cells each configured for controlling a load current and electrically connected to the first load terminal structure and to a drift region. A first mesa in the first cell includes a port region electrically connected to the first load terminal structure, and a first channel region coupled to the drift region. A second mesa included in the second cell includes a port region electrically connected to the first load terminal structure, and a second channel region coupled to the drift region. The mesas are spatially confined in a direction perpendicular to a direction of the load current by an insulation structure, and have a total extension of less than 100 nm in that direction. The first channel region includes an inversion channel. The second channel region includes an accumulation channel.