Abstract: A trench capacitor, in particular for use in a semiconductor memory cell, has a trench formed in a substrate; an insulation collar formed in an upper region of the trench; an optional buried plate in the substrate region serving as a first capacitor plate; a dielectric layer lining the lower region of the trench and the insulation collar as a capacitor dielectric; a conductive second filling material filled into the trench as a second capacitor plate; and a buried contact underneath the surface of the substrate. The substrate has, underneath its surface in the region of the buried contact, a doped region introduced by implantation, plasma doping and/or vapor phase deposition. A tunnel layer, in particular an oxide, nitride or oxinitride layer, is preferably formed at the interface of the buried contact. A method for producing a trench capacitor is also provided.

Abstract: The present invention provides a method for fabricating a semiconductor structure having a plurality of gate stacks (GS1, GS2, GS3, GS4) on a semiconductor substrate (10), having the following steps: application of the gate stacks (GS1, GS2, GS3, GS4) to a gate dielectric (11) above the semiconductor substrate (10); formation of a sidewall oxide (17) on sidewalls of the gate stacks (GS1, GS2, GS3, GS4); application and patterning of a mask (12) on the semiconductor structure; and implantation of a contact doping (13) in a self-aligned manner with respect to the sidewall oxide (17) of the gate stacks (GS1, GS2) in regions not covered by the mask (12).

Abstract: A memory having a memory cell formed in a substrate and including a trench capacitor and a transistor and a method for producing the memory includes connecting the trench capacitor to the transistor with a self-aligned connection. The transistor at least partly covers the trench capacitor. The trench capacitor is filled with a conductive trench filling and an insulating covering layer is situated on the conductive trench filling. An epitaxial layer is situated above the insulating covering layer. The transistor is formed in the epitaxial layer. The self-aligned connection is formed in a contact trench and includes an insulation collar in which a conductive material is introduced. A conductive cap is formed on the conductive material.

Abstract: A trench capacitor, in particular for use in a semiconductor memory cell, has a trench formed in a substrate; an insulation collar formed in an upper region of the trench; an optional buried plate in the substrate region serving as a first capacitor plate; a dielectric layer lining the lower region of the trench and the insulation collar as a capacitor dielectric; a conductive second filling material filled into the trench as a second capacitor plate; and a buried contact underneath the surface of the substrate. The substrate has, underneath its surface in the region of the buried contact, a doped region introduced by implantation, plasma doping and/or vapor phase deposition. A tunnel layer, in particular an oxide, nitride or oxinitride layer, is preferably formed at the interface of the buried contact.

Abstract: A memory having a memory cell formed in a substrate and including a trench capacitor and a transistor and a method for producing the memory includes connecting the trench capacitor to the transistor with a self-aligned connection. The transistor at least partly covers the trench capacitor. The trench capacitor is filled with a conductive trench filling and an insulating covering layer is situated on the conductive trench filling. An epitaxial layer is situated above the insulating covering layer. The transistor is formed in the epitaxial layer. The self-aligned connection is formed in a contact trench and includes an insulation collar in which a conductive material is introduced. A conductive cap is formed on the conductive material.

Abstract: A process is described which allows a buried, retrograde doping profile or a delta doping to be produced in a relatively simple and inexpensive way. The process uses individual process steps that are already used in the mass production of integrated circuits and accordingly can be configured for a high throughput.

Abstract: A method of fabricating an epitaxial layer includes providing a substrate having a substrate surface with an at least partly uncovered monocrytalline region, and at least one electrically insulating region adjoining the monocrystalline region and being at least partly surrounded by the monocrystalline region. An epitaxial layer is grown on the monocrystalline region. The electrically insulating region is at least partly overgrown laterally with the epitaxial layer, thereby forming an epitaxial closing joint above the electrically insulating region due to the overgrowth. The epitaxial layer is at least partly removed above the electrically insulating region, thereby the epitaxial closing joint is at least partly removed.