Abstract: A method for processing a wide band gap semiconductor wafer includes: depositing a support layer including semiconductor material at a back side of a wide band gap semiconductor wafer, the wide band gap semiconductor wafer having a band gap larger than the band gap of silicon; depositing an epitaxial layer at a front side of the wide band gap semiconductor wafer; and splitting the wide band gap semiconductor wafer along a splitting region to obtain a device wafer comprising at least a part of the epitaxial layer, and a remaining wafer comprising the support layer.

Abstract: A semiconductor device is described. The semiconductor device includes: a semiconductor substrate; a trench formed in a first main surface of the semiconductor substrate; a field plate electrode in the trench and reaching a same level as the first main surface of the semiconductor substrate; an insulating material that separates the field plate electrode from the semiconductor substrate; and a material embedded in the field plate electrode. The field plate electrode is made of a different material than the material embedded in the field plate electrode. The trench adjoins a region of the semiconductor substrate through which current flows in a first direction during operation of the semiconductor device. Additional device embodiments and methods of producing the semiconductor device are also described.

Abstract: A semiconductor device is described. The semiconductor device includes: a semiconductor substrate; an electrode structure on or in the semiconductor substrate, the electrode structure including an electrode and an insulating material that separates the electrode from the semiconductor substrate; and a strain-inducing material embedded in the electrode. The electrode structure adjoins a region of the semiconductor substrate through which current flows in a first direction during operation of the semiconductor device. The electrode is under either tensile or compressive stress in the first direction. The strain-inducing material either enhances or at least partly counteracts the stress of the electrode in the first direction. Methods of producing the semiconductor device are also described.

Abstract: A semiconductor device is described. The semiconductor device includes: a semiconductor substrate; an electrode structure on or in the semiconductor substrate, the electrode structure including an electrode and an insulating material that separates the electrode from the semiconductor substrate; and a strain-inducing material embedded in the electrode. The electrode structure adjoins a region of the semiconductor substrate through which current flows in a first direction during operation of the semiconductor device. The electrode is under either tensile or compressive stress in the first direction. The strain-inducing material either enhances or at least partly counteracts the stress of the electrode in the first direction. Methods of producing the semiconductor device are also described.

Abstract: A method for processing a wide band gap semiconductor wafer includes: depositing a support layer including semiconductor material at a back side of a wide band gap semiconductor wafer, the wide band gap semiconductor wafer having a band gap larger than the band gap of silicon; depositing an epitaxial layer at a front side of the wide band gap semiconductor wafer; and splitting the wide band gap semiconductor wafer along a splitting region to obtain a device wafer comprising at least a part of the epitaxial layer, and a remaining wafer comprising the support layer.

Abstract: A micromechanical structure includes a substrate and a functional structure arranged at the substrate. The functional structure has a functional region configured to deflect with respect to the substrate responsive to a force acting on the functional region. The functional structure includes a conductive base layer and a functional structure comprising a stiffening structure having a stiffening structure material arranged at the conductive base layer and only partially covering the conductive base layer at the functional region. The stiffening structure material includes a silicon material and at least a carbon material.

Abstract: A micromechanical structure includes a substrate and a functional structure arranged at the substrate. The functional structure has a functional region configured to deflect with respect to the substrate responsive to a force acting on the functional region. The functional structure includes a conductive base layer and a functional structure comprising a stiffening structure having a stiffening structure material arranged at the conductive base layer and only partially covering the conductive base layer at the functional region. The stiffening structure material includes a silicon material and at least a carbon material.