Abstract: A method of manufacturing a semiconductor device includes forming an amorphous silicon layer over a first isolation layer. The method further includes simultaneously forming a gate oxide layer of a transistor device and transforming the amorphous silicon layer into a polycrystalline silicon layer by a thermal oxidation process. Herein a cover oxide layer is formed on the polycrystalline silicon layer.

Abstract: The present invention relates to a method for differentiating in a subject with HR-HPV between a severe form of HR-HPV infection and a mild form of HR-HPV infection. It further is concerned with a composition comprising a probe oligonucleotide mixture, a device, and a kit for use in conjunction with the method of the invention.

Abstract: A semiconductor device include a semiconductor body with a drain region of a first conductivity type, a drift region of the first conductivity type and having a doping concentration lower than a doping concentration of the drain region, a buffer region of the first conductivity type arranged between the drift region and the drain region, a source region of the first conductivity type, a body region of a second conductivity type arranged between the source region and the drift region and forming a first pn-junction with the source region and a second pn-junction with the drift region, and a charge compensation region of the second conductivity type extending from the body region towards the buffer region. A source metallization is in ohmic contact with the source region. A drain metallization is ohmic contact with the drain region.

Abstract: A battery module with a plurality of battery cells (2), especially lithium ion battery cells (20), which are accommodated in a receiving space (6) formed by a housing (5) of the battery module (1), wherein the housing (5) of the battery module (1) furthermore forms a receiving element (7) designed to accommodate a cover plate (8), wherein a cover plate (8) is accommodated in the receiving element (7) in such a way that the cover plate (8) and the housing (5) form a flow space (9) through which a temperature-control fluid can flow, wherein the housing (5) of the battery module (1) furthermore separates the flow space (9) from the receiving space (6) in a fluid-tight manner.

Abstract: A battery module having at least one battery cell is disclosed, in particular a lithium-ion battery cell, comprising a housing, in which the at least one battery cell is accommodated, and a temperature-regulating element, wherein a Peltier element is furthermore arranged between the at least one battery cell and the temperature-regulating element, which Peltier element is thermally conductively connected in each case to the at least one battery cell and the temperature-regulating element, and which Peltier element is furthermore connected to a voltage source in such a way that heat transfer between the at least one battery cell and the temperature-regulating element is able to be formed by means of the Peltier element, wherein a compensation element for homogenizing the temperature, said compensation element being formed from a metallic material, is furthermore arranged between the at least one battery cell and the Peltier element, wherein preferably the at least one battery cell is directly or cohesively con

Abstract: A method of providing dynamic analysis for troubleshooting in vitro diagnostics instrument issues includes receiving, at a second computing device in communication with a plurality of instruments, identification of an issue associated with a portion of an instrument of the plurality of instruments, the identification received from a first computing device in communication with the instrument. A central computing device accesses data from one or more databases and determines an ordering of one or more corrective actions for resolving the issue by applying the data to a probabilistic model based on at least one of: patterns from the plurality of instruments; and operator input. The central computing device provides the one or more corrective actions in the determined order to the first computing device to be displayed via a user interface at the instrument.

Abstract: A battery module comprising a plurality of battery cells (2), in particular lithium-ion battery cells (20), which are received in a receptacle space (11) of the battery module (1), wherein the battery module (1) has a temperature-regulating plate (5) configured for regulating the temperature of the plurality of battery cells (2), said temperature-regulating plate furthermore forming a receptacle element (6) that receives a housing element (10) of the battery module (1) in such a way that the receptacle space (11) is closed off vis-à-vis the surroundings (12) of the battery module (1), wherein the housing element (10) is connected to the temperature-regulating plate (5) in a positively locking and/or force-locking manner by means of a securing element (8) formed by the temperature-regulating plate (5).

Abstract: A cooling plate (10) for the temperature control of at least one battery cell, especially for a traction battery, comprising a frame (12) with flow ducts (16) designed for the flowing of a coolant through them and a flexibly configured cover (14), which bounds the flow ducts (16) in fluid-tight manner and is provided for the thermal contacting of the at least one battery cell. It is proposed that the flow ducts (16) comprise at least one perturbing contour (28), which is provided to increase the turbulence in the coolant flowing through the flow ducts (16).

Abstract: A cooling plate (10) for temperature control of a battery cell, having a frame (12) with a coolant flow space (16) and at least one perturbing contour (30) inside the flow space (16), which is provided to increase turbulence in the coolant and is designed to support the at least one battery cell or for mechanical contacting with a cover (14) of the flow space (16). The perturbing contour (30) is arranged such that the coolant can flow around the perturbing contour (30) and the perturbing contour (30) is formed in the manner of at least one opening (50) in such a way that the coolant can flow through the at least one perturbing contour (30) and/or the frame (12) forms an opening (52) beneath the perturbing contour (30) in such a way that the coolant can flow beneath the at least one perturbing contour (30).

Abstract: A cooling plate (10) for controlling the temperature of at least one battery cell, in particular for a traction battery, having a frame (12), which forms a flow chamber (16) for a coolant to flow through, and a cover (14) of flexible design which delimits the flow chamber (16) in an at least partially fluid-tight manner and is provided for making thermal contact with the at least one battery cell. It is proposed that the cooling plate (10) has at least one supporting element (30), which is arranged within the flow chamber (16) and around which coolant can flow, for increasing the turbulence in the coolant flowing through the flow chamber (16) and for supporting the at least one battery cell, which supporting element makes mechanical contact with the cover (14) of flexible design.

Abstract: A battery having a plurality of battery cells accommodated in a housing, wherein a plurality of first battery cells are electrically connected to one another in series and/or in parallel, and a plurality of second battery cells are electrically connected to one another in series and/or in parallel, wherein the first battery cells each have a first outer surface and the second battery cells each have a second outer surface, wherein the housing of the battery has a first housing wall and a second housing wall, which is arranged opposite the first housing wall, wherein a first flow channel is formed between the first wall of the housing and the first outer surface of one of the first battery cells, and wherein a second flow channel is formed between the second wall of the housing and the second outer surface of one of the second battery cells.

Abstract: A battery module comprising a battery cell having a battery cell housing, and a battery module housing, wherein a coolant fluid intake is configured between the battery module housing and the battery cell housing, such that a direct and thermal contact is provided between the coolant fluid and the battery cell housing, wherein the battery cell housing further comprises a gas venting opening, which is configured to discharge gas from the interior of the battery cell housing directly to a surrounding environment, wherein the gas venting opening of the battery cell housing is isolated from the coolant fluid intake in a fluid-tight manner, wherein one lateral surface of the battery cell housing of the at least one battery cell , on which the gas venting opening is arranged, other than in the region of the gas venting opening , is essentially entirely enclosed by the coolant fluid intake.

Abstract: A transistor device includes at least one transistor cell, having, in a semiconductor body, a source region of a first doping type in a body region of a second doping type, a drain region, and a drift region of the first doping type adjoining the body region and arranged between the body region and the drain region. A low-resistance region of the second doping type in the body region adjoins the source region. A gate electrode dielectrically insulated from the source and body regions by a gate dielectric is arranged above a first surface of the semiconductor body. A length of an overlap between the source region and the gate electrode is larger than 70 nanometers. A doping profile of the low-resistance region along a line that is vertical to the first surface and goes through an edge of the gate electrode has a maximum of higher than 1E19 cm?3.

Abstract: Disclosed is a method for producing a transistor device and a transistor device. The method includes: forming a source region of a first doping type in a body region of a second doping type in a semiconductor body; and forming a low-resistance region of the second doping type adjoining the source region in the body region. Forming the source region includes implanting dopant particles of the first doping type using an implantation mask via a first surface of the semiconductor body into the body region. Implanting the doping particles of the first doping type includes a tilted implantation.

Abstract: A semiconductor device include a semiconductor body with a drain region of a first conductivity type, a drift region of the first conductivity type and having a doping concentration lower than a doping concentration of the drain region, a buffer region of the first conductivity type arranged between the drift region and the drain region, a source region of the first conductivity type, a body region of a second conductivity type arranged between the source region and the drift region and forming a first pn-junction with the source region and a second pn-junction with the drift region, and a charge compensation region of the second conductivity type extending from the body region towards the buffer region. A source metallization is in ohmic contact with the source region. A drain metallization is ohmic contact with the drain region.

Abstract: According to an embodiment, a method of forming a power semiconductor device is provided. The method includes providing a semiconductor substrate and forming an epitaxial layer on the semiconductor substrate. The epitaxial layer includes a body region, a source region, and a drift region. The method further includes forming a dielectric layer on the epitaxial layer. The dielectric layer is formed thicker above a drift region of the epitaxial layer than above at least part of the body region and the dielectric layer is formed at a temperature less than 950° C.

Abstract: The invention relates to a battery module having a multiplicity of battery cells (4), wherein the battery module (1) has a housing (2) with an interior space (3) in which the multiplicity of battery cells (4) is accommodated, wherein a housing wall (5, 6) of the housing (2) has a multiplicity of projections (7) facing toward the interior space (3) of the housing (2), wherein in each case two adjacent projections (7) delimit a flow channel (8) designed for a flow of temperature-control fluid, wherein the multiplicity of battery cells (4) makes direct contact in each case with the multiplicity of projections (7).

Abstract: A battery cell having a first housing element (4) which holds the electrochemical components of the battery cell (2) and has an opening (6), and a second housing element (5) which has a voltage tap (7) to be accessed from a first surface (8) of the second housing element (5), the second housing element (5) closes off the opening (6) so that a first part region (91) of a second surface (9) of the second housing element (5) is immediately adjacent the interior space (10) of the first housing element (4), and that a second part region (92) of the second surface (9) of the second housing element (5) protrudes beyond the first housing element (4), wherein the second housing element (5) comprises a sealing element (11) connected to the first surface (8) and/or to the second part region (92) of the second surface (9).

Abstract: A semiconductor device includes a semiconductor body having opposite first and second surfaces. The semiconductor device further includes a transistor structure in the semiconductor body and a source contact structure overlapping the transistor structure. The source contact structure is electrically connected to source regions of the transistor structure. A gate contact structure is further provided, which has a part separated from the source contact structure by a longitudinal gap within a lateral plane. Gate interconnecting structures bridge the longitudinal gap and are electrically coupled between the gate contact structure and a gate electrode of the transistor structure. Electrostatic discharge protection structures bridge the longitudinal gap and are electrically coupled between the gate contact structure and the source contact structure.

Abstract: A battery having a plurality of battery cells accommodated in a housing, wherein a plurality of first battery cells are electrically connected to one another in series and/or in parallel, and a plurality of second battery cells are electrically connected to one another in series and/or in parallel, wherein the first battery cells each have a first outer surface and the second battery cells each have a second outer surface, wherein the housing of the battery has a first housing wall and a second housing wall, which is arranged opposite the first housing wall, wherein a first flow channel is formed between the first wall of the housing and the first outer surface of one of the first battery cells, and wherein a second flow channel is formed between the second wall of the housing and the second outer surface of one of the second battery cells.