Abstract: A method of minimizing undercut of a hard mask in an integrated circuit (IC) structure including steps of providing an IC structure having a substrate, a interlayer dielectric layer, and a hard mask, forming a via in said IC structure, and depositing an organic planarizing layer (OPL) over the IC structure such that it fills the vias formed therein. The method also includes steps of forming a masking structure layer over the OPL, forming an opening in the masking structure that has a critical dimension (CD) smaller than an opening design dimension, anisotropic etching the OPL such that sidewall of the via remains covered with the OPL while forming a trench, and removing any remaining OPL on the sidewalls and trench, wherein the undercut of the sidewalls with respect to the hard mask is minimized by the covering of OPL during the anisotropic etching process.

Abstract: A method for producing a microelectronic structure is suggested in which a layer structure (30) which partially covers a substrate (5) and which comprises at least one first conductive layer (15,20) which reaches to a side wall (35) of the layer structure (30), is covered with a second conductive layer (45). The second conductive layer (45) is then subsequently back-etched to as great an extent as possible with an etching process with physical delamination, wherein delaminated material deposits on the side wall (35) of the layer structure (30). On the side wall (35) the delaminated material forms a protection layer (60) by means of which the first conductive layer (15,20) is to be protected from attack by oxygen to the furthest extent possible.

Abstract: Semiconductor devices and methods of manufacture thereof are disclosed. In a preferred embodiment, a semiconductor device includes a workpiece and a trench formed within the workpiece. The trench has an upper portion and a lower portion, the upper portion having a first width and the lower portion having a second width, the second width being greater than the first width. A first material is disposed in the lower portion of the trench at least partially in regions where the second width of the lower portion is greater than the first width of the upper portion. A second material is disposed in the upper portion of the trench and at least in the lower portion of the trench beneath the upper portion.

Abstract: In a method of fabricating a semiconductor device, a liner is deposited over a conductive region of a wafer and a stencil layer is deposited over the liner. The stencil layer and the liner are etched to form a stencil pattern for a conductive layer. A second liner is deposited over exposed surfaces of the stencil pattern, and the exposed horizontal surfaces of the second liner are removed by sputtering. A low-k dielectric layer is then deposited over the wafer, and the wafer is planarized down to the stencil pattern by chemical-mechanical polishing. The stencil pattern is removed with a wet etch to form an aperture in the wafer exposing the liner and remaining portions of the second liner. Metal is deposited in the aperture, and the surface of the wafer is replanarized by chemical-mechanical polishing to produce a planar surface for additional metallization layers that may be deposited.

Abstract: An interconnect stack and a method of manufacturing the same wherein the interconnect has vertical sidewall vias. The interconnect stack includes a substrate, a metal interconnect formed in the substrate, an etch stop formed on the substrate and the metal interconnect, and an interlayer dielectric (ILD) layer having at least one via formed therein extending through a transition layer formed on the etch stop layer. The via is formed by etching the ILD to a first depth and ashing the interconnect stack to modify a portion of the ILD between the portion of the via formed by etching and the transition layer. Ashing converts this portion of the ILD to an oxide material. The method includes wet etching the interconnect to remove the oxide material and a portion of the transition layer to form a via extending through the ILD to the etch stop layer.

Abstract: An integrated circuit interconnect structure includes a conductive line, a first barrier layer disposed on a bottom surface of conductive line, a second barrier layer disposed on the top surface of the conductive line, and an interlevel dielectric surrounding the conductive line.

Abstract: The invention relates to a method for producing a layer arrangement. An electrically conductive layer is formed and patterned. A sacrificial layer formed on at least part of the patterned electrically conductive layer. An electrically insulating layer is formed on the electrically conductive and sacrificial layers and is patterned in such a manner that one or more surface areas of the sacrificial layer are exposed. The exposed areas of the sacrificial layer are removed to expose one or more surface areas of the patterned electrically conductive layer. The patterned electrically conductive layer is covered with a pattern of electrically conductive material.

Abstract: In a method of fabricating a semiconductor device, a liner is deposited over a conductive region of a wafer and a stencil layer is deposited over the liner. The stencil layer and the liner are etched to form a stencil pattern for a conductive layer. A second liner is deposited over exposed surfaces of the stencil pattern, and the exposed horizontal surfaces of the second liner are removed by sputtering. A low-k dielectric layer is then deposited over the wafer, and the wafer is planarized down to the stencil pattern by chemical-mechanical polishing. The stencil pattern is removed with a wet etch to form an aperture in the wafer exposing the liner and remaining portions of the second liner. Metal is deposited in the aperture, and the surface of the wafer is replanarized by chemical-mechanical polishing to produce a planar surface for additional metallization layers that may be deposited.

Abstract: Methods of forming air gaps between interconnects of integrated circuits and structures thereof are disclosed. A first insulating material is deposited over a workpiece, and a second insulating material having a sacrificial portion is deposited over the first insulating material. Conductive lines are formed in the first and second insulating layers. The second insulating material is treated to remove the sacrificial portion, and at least a portion of the first insulating material is removed, forming air gaps between the conductive lines. The second insulating material is impermeable as deposited and permeable after treating it to remove the sacrificial portion. A first region of the workpiece may be masked during the treatment, so that the second insulating material becomes permeable in a second region of the workpiece yet remains impermeable in the first region, thus allowing the formation of the air gaps in the second region, but not the first region.

Abstract: To form a semiconductor device, a silicon (e.g., polysilicon) gate layer is formed over a gate dielectric and a sacrificial layer (preferably titanium nitride) is formed over the silicon gate layer. The silicon gate layer and the sacrificial layer are patterned to form a gate structure. A spacer, such as an oxide sidewall spacer and a nitride sidewall spacer, is formed adjacent the sidewall of the gate structure. The semiconductor body is then doped to form a source region and a drain region that are self-aligned to the spacers. The sacrificial layer can then be removed selectively with respect to the oxide sidewall spacer, the nitride sidewall spacer and the silicon gate. A metal layer (e.g., nickel) is formed over the source region, the drain region and the silicon gate and reacted with these regions to form a silicided source contact, a silicided drain contact and a silicided gate.

Abstract: The electrode configuration includes at least one structured layer. A mask is produced on the layer to be structured and the layer is dry etched. The mask is at least slightly etchable by dry etching. The mask contains a metal silicide, a metal nitride or a metal oxide.

Abstract: A reactor configuration contains a housing connected to a silicon wafer. The silicon wafer has pores extending from a first main area of the silicon wafer into an interior of the silicon wafer, preferably as far as a second main area of the silicon wafer. A catalyst layer at least partly covers the surface of the pores.

Abstract: A ferroelectric transistor suitable as a memory element has a first gate intermediate layer and a first gate electrode disposed on the surface of a semiconductor substrate and disposed between source/drain regions. The first gate intermediate layer contains at least one ferroelectric layer. In addition to the first gate intermediate layer, a second gate intermediate layer and a second gate electrode are configured between the source/drain regions. The second gate intermediate layer contains a dielectric layer. The first gate electrode and the second gate electrode are connected to each other via a diode structure.

Abstract: A microelectronic structure that is suitable, in particular, as part of a storage capacitor includes a semiconductor structure, a barrier structure, an electrode structure, and a dielectric structure made of a high-epsilon material. The electrode structure has a tensile mechanical layer stress. The microelectronic structure is fabricated, in particular, by sputtering platinum in order to form the electrode structure at a sputtering temperature of at least 200° C.

Abstract: A cleaning process for cleaning CVD units is disclosed. In the cleaning process, alkaline earth metal and/or metal-containing process residues, which form an amorphous film on reactor walls, are removed using a dry etching medium containing free diketones at a greatly reduced pressure and an elevated temperature. In the process, the free diketones react with the alkaline earth metals or metals to form volatile complexes.

Abstract: An optical structure includes a substrate having semiconductor material and a grating structure. The grating structure has the property of emitting at least one frequency band so that light having a frequency from that frequency band cannot propagate in the grating structure. The grating structure has a configuration of pores and a defective region. The pores are disposed outside the defective region in a periodic array, and the periodic array is disturbed in the defective region. A surface of the grating structure is provided with a conductive layer at least in the vicinity of the defective region. A method for producing the optical structure is also provided.

Abstract: The invention relates to a microelectronic structure. In the structure, an oxygen-containing iridium layer is embedded between a silicon-containing layer and an oxygen barrier layer. The iridium layer is especially produced by a sputter process in an oxygen atmosphere with a low oxygen content. The oxygen-containing iridium layer is stale at temperatures up to 800° C. and withstands the formation of iridium silicide upon contact with the silicon-containing layer. Such micro-electronic structures are preferably used in semiconductor memories.

Abstract: A substrate made from silicon has a first region and a second region. Through pores are formed in the first region. Pores that do not traverse the substrate are provided in the second region. The production of the work piece is performed with the aid of electrochemical etching of the pores. The entire surface of the substrate is covered with a mask layer that is structured photolithographically on the rear of the substrate. The bottoms of the pores in the second region are etched clear, preferably using KOH.

Abstract: A DRAM capacitor is described that contains a BaSrTiO3 (BST) dielectric. The dielectric has a three-layer structure enabling the formation of a potential trough in which electrons can be permanently trapped.

Abstract: A storage capacitor for a DRAM has a dielectric composed of silicon nitride and has at least two electrodes disposed opposite one another across the dielectric. A material having a high tunneling barrier between the Fermi level of the material and the conduction band of the dielectric is used for the electrodes. Suitable materials for the electrodes are metals such as platinum, tungsten and iridium or silicides.