Abstract: The present disclosure provides in one aspect a semiconductor device including a substrate structure comprising an active semiconductor material formed over a base substrate and a buried insulating material formed between the active semiconductor material and the base substrate, a ferroelectric gate structure disposed over the active semiconductor material in an active region of the substrate structure, the ferroelectric gate structure comprising a gate electrode and a ferroelectric material layer, and a contact region formed in the base substrate under the ferroelectric gate structure.

Abstract: The present disclosure provides in one aspect a semiconductor device including a substrate structure comprising an active semiconductor material formed over a base substrate and a buried insulating material formed between the active semiconductor material and the base substrate, a ferroelectric gate structure disposed over the active semiconductor material in an active region of the substrate structure, the ferroelectric gate structure comprising a gate electrode and a ferroelectric material layer, and a contact region formed in the base substrate under the ferroelectric gate structure.

Abstract: A device and method for depositing a protective layer on a material during a plasma etching procedure in the course of fabricating semiconductor components, in particular in the course of fabricating DRAM chips, characterized in that the plasma has at least one precursor which, during the plasma etching procedure, together with a constituent of the plasma at least partially forms a protective layer on a planar region of the material and, characterized by a means for feeding the at least one precursor into the plasma, in which case, by means of the at least one precursor, during the plasma etching procedure, together with a constituent of the plasma, a protective layer can at least partially be deposited on a planar region of the material.

Abstract: A method for operating a plasma reactor to etch high-aspect-ratio features on a workpiece in a vacuum chamber. The method comprises the performance of an etch process followed by a flash process. During the etch process, a first gas is supplied into the vacuum chamber, and a plasma of the first gas is maintained for a first period of time. The plasma of the first gas comprises etchant and passivant species. During the flash process, a second gas comprising a deposit removal gas is supplied into the vacuum chamber, and a plasma of the second gas is maintained for a second period of time. The DC voltage between the workpiece and the plasma of the second gas during the second period of time is significantly less than the DC voltage between the workpiece and the plasma of the first gas during the first period of time.

Abstract: A method for operating a plasma reactor to etch high-aspect-ratio features on a workpiece in a vacuum chamber. The method comprises the performance of an etch process followed by a flash process. During the etch process, a first gas is supplied into the vacuum chamber, and a plasma of the first gas is maintained for a first period of time. The plasma of the first gas comprises etchant and passivant species. During the flash process, a second gas comprising a deposit removal gas is supplied into the vacuum chamber, and a plasma of the second gas is maintained for a second period of time. The DC voltage between the workpiece and the plasma of the second gas during the second period of time is significantly less than the DC voltage between the workpiece and the plasma of the first gas during the first period of time.