The invention relates to the chemical etching of a semiconductor material, including: deposition at least one mask (PLP) on a first surface zone of a semiconductor material (SC); and chemically etching (S31) a second surface zone of the semiconductor material (SC) that is not covered by the mask (PLP). In particular, the aforementioned mask is produced in a material including polyphosphazene, which material protects the underlying semiconductor especially well.

A method for forming an antifuse on a substrate is provided, which comprises: forming a first conductive material on the substrate; placing the first conductive material in an electrolytic solution; performing anodic oxidation on the first conductive material to form a nanowire made of the first conductive material and surrounded by a first dielectric material formed during the anodic oxidation and to form the antifuse on the nanowire; and forming a second conductive material on the antifuse to sandwich the antifuse between the first conductive material and the second conductive material.

A porous region structure and a method of fabrication thereof are disclosed. The porous region structure is characterized by having a hard mask interface region with non-uniform pores sealed and thereby excluded functionally from the structure. The sealing of the hard mask interface region is done using a hard mask deposited on top of an anodization hard mask used to define the porous region of the structure. By excluding the hard mask interface region, the porosity ratio and the equivalent specific surface of the porous region structure can be controlled or quantified with higher accuracy. Corrosion due to exposure of an underlying metal layer of the structure is also significantly reduced by sealing the hard mask interface region.

Structures, devices and methods are provided for forming nanowires on a substrate. A first protruding structure is formed on a substrate. The first protruding structure is placed in an electrolytic solution. Anodic oxidation is performed using the substrate as part of an anode electrode. One or more nanowires are formed in the protruding structure. The nanowires are surrounded by a first dielectric material formed during the anodic oxidation.

A method includes depositing a plurality of first semiconductor layers and a plurality of second semiconductor layers over a substrate, wherein the first semiconductor layers and the second semiconductor layers are stacked alternately; patterning the first and second semiconductor layers to form a fin structure; supplying a first bias to the substrate after patterning the first and second semiconductor layers; and etching the second semiconductor layers when the semiconductor substrate is supplied with the first bias, wherein etching the second semiconductor layers is performed such that the first semiconductor layers are suspended above the substrate.

A semiconductor device that includes a semiconductor substrate having a first main surface and a second main surface opposed to each other, and a porous metal oxide film on a side of the first main surface of the semiconductor substrate, the porous metal oxide film having a plurality of pores. The semiconductor substrate has a connection electrically connected to the porous metal oxide film, and the semiconductor substrate is configured to provide a power supply path from the second main surface to the connection on the first main surface.

A method includes forming a semiconductor fin on a semiconductor substrate, the semiconductor fin comprising germanium, silicon, silicon germanium or any of III-V elements; forming a mask layer on a top portion of the semiconductor fin; and trimming the semiconductor fin, wherein trimming the semiconductor fin comprises: immersing the semiconductor substrate in a first electrolyte bath; and laterally removing a first portion of the semiconductor fin by supplying a first voltage to a counter electrode in the electrolyte bath and a second voltage to the semiconductor substrate, wherein the second voltage is negative.

A method of manufacturing a semiconductor device includes forming an auxiliary mask including a plurality of mask openings on a main surface of a crystalline semiconductor substrate. A porous structure is formed in the semiconductor substrate. The porous structure includes a porous layer at a distance to the main surface and porous columns that extend from the porous layer into direction of the main surface and that are laterally separated from each other by a non-porous portion. A non-porous device layer is formed on the non-porous portion and on the porous columns.

The invention relates to the chemical etching of a semiconductor material, including: deposition at least one mask (PLP) on a first surface zone of a semiconductor material (SC); and chemically etching (S31) a second surface zone of the semiconductor material (SC) that is not covered by the mask (PLP).

In particular, the aforementioned mask is produced in a material including polyphosphazene, which material protects the underlying semiconductor especially well.

A silicon carbide device includes a silicon carbide substrate having a body region and a source region of a transistor cell. Further, the silicon carbide device includes a titanium carbide gate electrode of the transistor cell.