Abstract: A carbon hard mask layer is applied to a substrate to be patterned by means of a plasma-enhanced deposition process in such a manner that it has a hardness comparable to that of diamond in at least one layer thickness section. During the production of this diamond-like layer thickness section, the parameters used in the deposition are set in such a manner that growth regions which are produced in a form other than diamond-like are removed again in situ by means of subsequent etching processes and that diamond-like regions which are formed are retained.

Abstract: A method for producing a semiconductor structure including preparing a semiconductor substrate, and generating a lower first, a middle second and an upper third masking layer on a surface of the semiconductor substrate. The method further includes forming at least one first window in the upper third masking layer, structuring the middle second masking layer using the first window for transferring the first window, structuring the lower first masking layer using the first window for transferring the first window, and enlarging the first window to form a second window. The method for further includes restructuring the middle second masking layer using the second window for transferring the second window, structuring the semiconductor substrate, using the structured lower third masking layer, restructuring the lower first masking layer using the second window, and restructuring the semiconductor substrate using the restructured lower third masking layer.

Abstract: Recesses between gate layer stacks are filled with a first electrically insulating material. Cavities or voids are opened up during the removal of a portion of the first insulating material. These voids are filled during the application of a conductive layer and can then lead to short circuits. Inventively, a layer for closing up voids is produced before the conductive material is applied, as a result of growing a second electrically insulating material onto the surface of the remaining first insulating material. This second insulating layer closes up voids that have formed in the first insulating material so that they can no longer lead to short circuits. In particular, voids that are difficult to gain access to and open out into side walls of contact holes can in this way be closed up in a simple manner.

Abstract: A method for producing a semiconductor structure including preparing a semiconductor substrate, and generating a lower first, a middle second and an upper third masking layer on a surface of the semiconductor substrate. The method further includes forming at least one first window in the upper third masking layer, structuring the middle second masking layer using the first window for transferring the first window, structuring the lower first masking layer using the first window for transferring the first window, and enlarging the first window to form a second window. The method for further includes restructuring the middle second masking layer using the second window for transferring the second window, structuring the semiconductor substrate, using the structured lower third masking layer, restructuring the lower first masking layer using the second window, and restructuring the semiconductor substrate using the restructured lower third masking layer.

Abstract: To form a pattern in a semiconductor substrate, a buffer layer, which is formed as a carbon layer, is produced between a photoresist layer and an antireflective layer, which is formed on the substrate. The pattern is produced in the photoresist layer by means of a lithography step, and then it is transferred to the layers arranged below in a subsequent step.

Abstract: A method for filling depressions in a surface of a semiconductor structure, and a semiconductor structure filled in this way. On a semiconductor structure, in depressions on the surface, in particular below the first metal structure plane, a diffusion barrier layer is deposited, preferably with the aid of plasma-enhanced vapor phase deposition, during which the ions contained in the plasma are accelerated perpendicularly to the surface, resulting in non-conformal deposition of the diffusion barrier layer.

Abstract: A method for fabricating an insulator on a semiconductor substrate such that the insulator has a low dielectric constant. A first interconnect and a second interconnect are configured on a semiconductor substrate. A conductive silicon is formed between the first interconnect and the second interconnect. The conductive silicon is anodically etched in a hydrofluoric-acid-containing electrolyte to convert the conductive silicon into porous silicon. The porous silicon is subsequently oxidized to form porous silicon oxide. With a dielectric constant of between 1.1 and 4, the porous silicon oxide has a lower dielectric constant than customary silicon oxide with 4.

Abstract: A method in which a recess is formed in the surface of a semiconductor substrate and a material is grown on the inner wall of the recess, includes the steps of producing an electrically insulating layer on the surface of the substrate outside the recess, and selectively growing the material on the inner wall of the recess as a result of the substrate, as an electrode, being brought into contact with an electrolysis liquid and electrolysis being carried out, during which the insulating layer prevents the material from growing outside the recess. Before the electrolysis is carried out, a reserve material is epitaxially deposited on the inner wall of the recess and, during the electrolysis, the reserve material is converted into the material being grown by electrolysis.

Abstract: A method for forming a trench in a semiconductor substrate includes configuring a mask on the substrate. The mask has a window in which a substrate surface is uncovered. The substrate is electrochemically etched proceeding from the substrate surface. A porous substrate is formed in a trench-shaped region proceeding from the substrate surface. The trench is formed by removing the porous substrate from the trench-shaped region.

Abstract: A method of filling gaps on a semiconductor wafer with a dielectric material employs a plasma enhanced chemical vapor deposition (PECVD) process with a temperature in the range of 500 to 700° C. As a result of the deposition process, gaps resulting from e.g. shallow trench isolation or premetal dielectric techniques are filled homogeneously without any voids. The deposition may be improved by applying two radio frequency signals with different frequencies.

Abstract: A first silicon-containing reaction gas and an oxygen precursor representing a further reaction gas are fed to the reaction chamber and a high-density plasma, preferably above 1016 ions/m3, is produced. Through at least partial substitution of the precursor O2 that is normally used, H2O2 and/or H2O are fed to the reaction chamber in order to further reduce the sputtering effects due to O2 ions during the deposition, which lead to undesirable redepositions of the SiO2 on side walls of the depression.

Abstract: Recesses between gate layer stacks are filled with a first electrically insulating material. Cavities or voids are opened up during the removal of a portion of the first insulating material. These voids are filled during the application of a conductive layer and can then lead to short circuits. Inventively, a layer for closing up voids is produced before the conductive material is applied, as a result of growing a second electrically insulating material onto the surface of the remaining first insulating material. This second insulating layer closes up voids that have formed in the first insulating material so that they can no longer lead to short circuits. In particular, voids that are difficult to gain access to and open out into side walls of contact holes can in this way be closed up in a simple manner.

Abstract: A method in which a recess is formed in the surface of a semiconductor substrate and a material is grown on the inner wall of the recess, includes the steps of producing an electrically insulating layer on the surface of the substrate outside the recess, and selectively growing the material on the inner wall of the recess as a result of the substrate, as an electrode, being brought into contact with an electrolysis liquid and electrolysis being carried out, during which the insulating layer prevents the material from growing outside the recess. Before the electrolysis is carried out, a reserve material is epitaxially deposited on the inner wall of the recess and, during the electrolysis, the reserve material is converted into the material being grown by electrolysis.

Abstract: A process for fabricating a device including the step of forming a structure for facilitating the passivation of surface states is disclosed. The structure comprises an oxynitride layer formed as part of the device structure. The oxynitride facilitates the passivation of surface states when heated.

Abstract: In order to fabricate a dynamic memory cell configuration with a long retention time, a hydrogen heat treatment of the wafer is carried out after the production of the interconnect system. The hydrogen heat treatment is performed in a PECVD reactor into which hydrogen is introduced and excited in the plasma. The heat treatment becomes more effective as a result and can be combined with deposition processes, in particular of passivation layers, carried out in PECVD installations.

Abstract: A method for the shrink-hole-free filling of trenches in semiconductor circuits which utilizes selective growth of a layer to be applied is described. In the method, a layer of a selective growing material is applied simultaneously to a growth-promoting layer and to a growth-inhibiting layer. Wherein raised portions which, before the layer of selective growing material is applied, are covered by the growth-inhibiting layer at least on their sides. After the growth-inhibiting layer has been applied, the growth-promoting layer is generated by anisotropic treatment on surfaces parallel to the substrate on and between the raised portions and the layer is then removed again on surfaces parallel to the substrate on the raised portions. The method makes it possible to produce in a particularly simple manner a pattern on the raised portions of which are covered by the growth-inhibiting layer on their sides and on their top whereas the bottom of trenches is covered with a growth-promoting layer.

Abstract: The present invention relates to a dielectric filling for electrical wiring planes of an integrated circuit. The electrical wiring of the integrated circuit comprises a base body on which track and passivation planes can already be disposed; a conductive layer which is disposed on the base body and is patterned in such a manner that it exhibits a first conductor track, a second conductor track and a trench between the first conductor track and the second conductor track; at least one dielectric layer is disposed on the conductive layer and at least partially fills the trench, the preferred material of the dielectric layer being the polymer material polybenzoxazole.

Abstract: A method of filling gaps on a semiconductor wafer with a dielectric material employs a plasma enhanced chemical vapor deposition (PECVD) process with a temperature in the range of 500 to 700° C. As a result of the deposition process, gaps resulting from e.g. shallow trench isolation or premetal dielectric techniques are filled homogeneously without any voids. The deposition may be improved by applying two radio frequency signals with different frequencies.

Abstract: A method for fabricating an insulator on a semiconductor substrate such that the insulator has a low dielectric constant. A first interconnect and a second interconnect are configured on a semiconductor substrate. A conductive silicon is formed between the first interconnect and the second interconnect. The conductive silicon is anodically etched in a hydrofluoric-acid-containing electrolyte to convert the conductive silicon into porous silicon. The porous silicon is subsequently oxidized to form porous silicon oxide. With a dielectric constant of between 1.1 and 4, the porous silicon oxide has a lower dielectric constant than customary silicon oxide with 4.

Abstract: A method for forming a trench in a semiconductor substrate includes configuring a mask on the substrate. The mask has a window in which a substrate surface is uncovered. The substrate is electrochemically etched proceeding from the substrate surface. A porous substrate is formed in a trench-shaped region proceeding from the substrate surface. The trench is formed by removing the porous substrate from the trench-shaped region.