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 method of manufacturing a power semiconductor device includes: creating a doped contact region on top of a surface of a carrier; creating, on top of the contact region, a doped transition region having a maximum dopant concentration of at least 0.5*1015 cm?3 for at least 70% of a total extension of the doped transition region in an extension direction and a maximal dopant concentration gradient of at most 3*1022 cm?4, wherein a lower subregion of the doped transition region is in contact with the contact region and has a maximum dopant concentration at least 100 times higher than a maximum dopant concentration of an upper subregion of the doped transition region; and creating a doped drift region on top of the upper subregion of the doped transition region, the doped drift region having a lower dopant concentration than the upper subregion of the doped transition region.

Abstract: An embodiment of a method for manufacturing a semiconductor device includes: providing a monocrystalline semiconductor substrate having a first side; forming a plurality of recess structures in the semiconductor substrate at the first side; filling the recess structures with a dielectric material to form dielectric islands in the recess structures; forming a semiconductor layer on the first side of the semiconductor substrate to cover the dielectric islands; and subjecting the semiconductor layer to heat treatment and recrystallizing the semiconductor layer to form a recrystallized semiconductor layer, so that a crystal structure of the recrystallized semiconductor layer adapts to a crystal structure of the semiconductor substrate, and so that the semiconductor substrate and the semiconductor layer together form a compound wafer with the dielectric islands at least partially buried in the semiconductor material of the compound wafer.

Abstract: A method of producing a semiconductor device is presented. The method comprises: providing a semiconductor substrate having a surface; epitaxially growing, along a vertical direction (Z) perpendicular to the surface, a back side emitter layer on top of the surface, wherein the back side emitter layer has dopants of a first conductivity type or dopants of a second conductivity type complementary to the first conductivity type; epitaxially growing, along the vertical direction (Z), a drift layer having dopants of the first conductivity type above the back side emitter layer, wherein a dopant concentration of the back side emitter layer is higher than a dopant concentration of the drift layer; and creating, either within or on top of the drift layer, a body region having dopants of the second conductivity type, a transition between the body region and the drift layer forming a pn-junction (Zpn).

Abstract: A CVD reactor, including a deposition chamber housing a first susceptor and a second susceptor, the first susceptor having a cavity for receiving a first substrate, the first substrate having a front surface and a back surface, the second susceptor having a cavity for receiving a second substrate, the second substrate having a front surface and a back surface, and the first susceptor and the second susceptor are disposed so that the front surface of the first substrate is opposite to the front surface of the second substrate thereby forming a portion of a gas flow channel.

Abstract: A method for forming a power semiconductor device is provided. The method includes: providing a semiconductor wafer grown by a Czochralski process and having a first side; forming an n-type substrate doping layer in the semiconductor wafer at the first side, the substrate doping layer having a doping concentration of at least 1017/cm3; and forming an epitaxy layer on the first side of the semiconductor wafer after forming the n-type substrate doping layer.

Abstract: A power semiconductor device has a semiconductor body configured to conduct a load current in parallel to an extension direction between first and second load terminals of the power semiconductor device. The semiconductor body includes a doped contact region electrically connected to the second load terminal, a doped drift region having a dopant concentration that is smaller than a dopant concentration of the contact region, and an epitaxially grown doped transition region separated from the second load terminal by the contact region and that couples the contact region to the drift region. An upper subregion of the transition region is in contact with the drift region, and a lower subregion of the transition region is in contact with the contact region. The transition region has a dopant concentration of at least 0.5*1015 cm?3 for at least 5% of the total extension of the transition region in the extension direction.

Abstract: A method of fabricating a semiconductor device includes forming a buried insulation region within a substrate by processing the substrate using etching and deposition processes. A semiconductor layer is formed over the buried insulation region at a first side of the substrate. Device regions are formed in the semiconductor layer. The substrate is thinned from a second side of the substrate to expose the buried insulation region. The buried insulation region is selectively removed to expose a bottom surface of the substrate. A conductive region is formed under the bottom surface of the substrate.

Abstract: According to various embodiments, a semiconductor wafer may include: a semiconductor body including an integrated circuit structure; and at least one tetrahedral amorphous carbon layer formed at least one of over or in the integrated circuit structure, the at least one tetrahedral amorphous carbon layer may include a substance amount fraction of sp3-hybridized carbon of larger than approximately 0.4 and a substance amount fraction of hydrogen smaller than approximately 0.1.

Abstract: A power semiconductor device has a semiconductor body configured to conduct a load current in parallel to an extension direction between first and second load terminals of the power semiconductor device. The semiconductor body includes a doped contact region electrically connected to the second load terminal, a doped drift region having a dopant concentration that is smaller than a dopant concentration of the contact region, and an epitaxially grown doped transition region separated from the second load terminal by the contact region and that couples the contact region to the drift region. An upper subregion of the transition region is in contact with the drift region, and a lower subregion of the transition region is in contact with the contact region. The transition region has a dopant concentration of at least 0.5*1015 cm?3 for at least 5% of the total extension of the transition region in the extension direction.

Abstract: A semiconductor device includes a drift region extending from a first surface into a semiconductor portion. A body region between two portions of the drift region forms a first pn junction with the drift region. A source region forms a second pn junction with the body region. The pn junctions include sections perpendicular to the first surface. Gate structures extend into the body regions and include a gate electrode. Field plate structures extend into the drift region and include a field electrode separated from the gate electrode. A gate shielding structure is configured to reduce a capacitive coupling between the gate structures and a backplate electrode directly adjoining a second surface.

Abstract: In one aspect, a method of forming a trench in a semiconductor material includes forming a first dielectric layer on a semiconductor substrate. The first dielectric layer includes first openings. An epitaxial layer is grown on the semiconductor substrate by an epitaxial lateral overgrowth process. The first openings are filled by the epitaxial layer and the epitaxial layer is grown onto adjacent portions of the first dielectric layer so that part of the first dielectric layer is uncovered by the epitaxial layer and a gap forms between opposing sidewalls of the epitaxial layer over the part of the first dielectric layer that is uncovered by the epitaxial layer. The gap defines a first trench in the epitaxial layer that extends to the first dielectric layer.

Abstract: A method of producing a semiconductor device is presented. The method comprises: providing a semiconductor substrate having a surface; epitaxially growing, along a vertical direction (Z) perpendicular to the surface, a back side emitter layer on top of the surface, wherein the back side emitter layer has dopants of a first conductivity type or dopants of a second conductivity type complementary to the first conductivity type; epitaxially growing, along the vertical direction (Z), a drift layer having dopants of the first conductivity type above the back side emitter layer, wherein a dopant concentration of the back side emitter layer is higher than a dopant concentration of the drift layer; and creating, either within or on top of the drift layer, a body region having dopants of the second conductivity type, a transition between the body region and the drift layer forming a pn-junction (Zpn).

Abstract: Trenches are formed in a semiconductor layer of a semiconductor substrate. A mixture that contains trichlorosilane and hydrogen gas is fed into a process chamber containing the semiconductor substrate. A barometric pressure in the process chamber is at least 50% of standard atmosphere. The trenches are filled with epitaxially deposited crystalline silicon.

Abstract: A method of producing a semiconductor device is presented. The method comprises: providing a semiconductor substrate having a surface; epitaxially growing, along a vertical direction (Z) perpendicular to the surface, a back side emitter layer on top of the surface, wherein the back side emitter layer has dopants of a first conductivity type or dopants of a second conductivity type complementary to the first conductivity type; epitaxially growing, along the vertical direction (Z), a drift layer having dopants of the first conductivity type above the back side emitter layer, wherein a dopant concentration of the back side emitter layer is higher than a dopant concentration of the drift layer; and creating, either within or on top of the drift layer, a body region having dopants of the second conductivity type, a transition between the body region and the drift layer forming a pn-junction (Zpn).

Abstract: A semiconductor device includes a drift region extending from a first surface into a semiconductor portion. A body region between two portions of the drift region forms a first pn junction with the drift region. A source region forms a second pn junction with the body region. The pn junctions include sections perpendicular to the first surface. Gate structures extend into the body regions and include a gate electrode. Field plate structures extend into the drift region and include a field electrode separated from the gate electrode. A gate shielding structure is configured to reduce a capacitive coupling between the gate structures and a backplate electrode directly adjoining a second surface.

Abstract: A method of producing a semiconductor device is presented. The method comprises: providing a semiconductor substrate having a surface; epitaxially growing, along a vertical direction (Z) perpendicular to the surface, a back side emitter layer on top of the surface, wherein the back side emitter layer has dopants of a first conductivity type or dopants of a second conductivity type complementary to the first conductivity type; epitaxially growing, along the vertical direction (Z), a drift layer having dopants of the first conductivity type above the back side emitter layer, wherein a dopant concentration of the back side emitter layer is higher than a dopant concentration of the drift layer; and creating, either within or on top of the drift layer, a body region having dopants of the second conductivity type, a transition between the body region and the drift layer forming a pn-junction (Zpn).

Abstract: In one aspect, a method of forming a trench in a semiconductor material includes forming a first dielectric layer on a semiconductor substrate. The first dielectric layer includes first openings. An epitaxial layer is grown on the semiconductor substrate by an epitaxial lateral overgrowth process. The first openings are filled by the epitaxial layer and the epitaxial layer is grown onto adjacent portions of the first dielectric layer so that part of the first dielectric layer is uncovered by the epitaxial layer and a gap forms between opposing sidewalls of the epitaxial layer over the part of the first dielectric layer that is uncovered by the epitaxial layer. The gap defines a first trench in the epitaxial layer that extends to the first dielectric layer.

Abstract: In one aspect, a method of forming a trench in a semiconductor material includes forming a first dielectric layer on a semiconductor substrate. The first dielectric layer includes first openings. An epitaxial layer is grown on the semiconductor substrate by an epitaxial lateral overgrowth process. The first openings are filled by the epitaxial layer and the epitaxial layer is grown onto adjacent portions of the first dielectric layer so that part of the first dielectric layer is uncovered by the epitaxial layer and a gap forms between opposing sidewalls of the epitaxial layer over the part of the first dielectric layer that is uncovered by the epitaxial layer. The gap defines a first trench in the epitaxial layer that extends to the first dielectric layer.

Abstract: According to various embodiments, a semiconductor wafer may include: a semiconductor body including an integrated circuit structure; and at least one tetrahedral amorphous carbon layer formed at least one of over or in the integrated circuit structure, the at least one tetrahedral amorphous carbon layer may include a substance amount fraction of sp3-hybridized carbon of larger than approximately 0.4 and a substance amount fraction of hydrogen smaller than approximately 0.1.