361 results about "Integrated circuit fabrication" patented technology

Different sized features in the array and in the periphery of an integrated circuit are patterned on a substrate in a single step. In particular, a mixed pattern, combining two separately formed patterns, is formed on a single mask layer and then transferred to the underlying substrate. The first of the separately formed patterns is formed by pitch multiplication and the second of the separately formed patterns is formed by conventional photolithography. The first of the separately formed patterns includes lines that are below the resolution of the photolithographic process used to form the second of the separately formed patterns. These lines are made by forming a pattern on photoresist and then etching that pattern into an amorphous carbon layer. Sidewall pacers having widths less than the widths of the un-etched parts of the amorphous carbon are formed on the sidewalls of the amorphous carbon. The amorphous carbon is then removed, leaving behind the sidewall spacers as a mask pattern. Thus, the spacers form a mask having feature sizes less than the resolution of the photolithography process used to form the pattern on the photoresist. A protective material is deposited around the spacers. The spacers are further protected using a hard mask and then photoresist is formed and patterned over the hard mask. The photoresist pattern is transferred through the hard mask to the protective material. The pattern made out by the spacers and the temporary material is then transferred to an underlying amorphous carbon hard mask layer. The pattern, having features of difference sizes, is then transferred to the underlying substrate.

A method of forming a boride layer for integrated circuit fabrication is disclosed. In one embodiment, the boride layer is formed by chemisorbing monolayers of a boron-containing compound and one refractory metal compound onto a substrate. In an alternate embodiment, the boride layer has a composite structure. The composite boride layer structure comprises two or more refractory metals. The composite boride layer is formed by sequentially chemisorbing monolayers of a boron compound and two or more refractory metal compounds on a substrate.

A method for integrated circuit fabrication can include removing silicon oxide by a pre-clean process. The pre-clean process can include depositing a halogen-containing material on the surface of a substrate in a first reaction chamber, and transferring the substrate having the halogen-containing material to a second reaction chamber. Silicon oxide material can be removed from a surface of the substrate by sublimating the halogen-containing material in the second reaction chamber. A target material, such as a conductive material, may subsequently be deposited on the substrate surface in the second reaction chamber.

In some embodiments, a method for integrated circuit fabrication includes removing oxide material from a surface of a substrate, where the surface includes silicon and germanium. Removing the oxide material includes depositing a halogen-containing pre-clean material on a silicon oxide-containing surface and sublimating a portion of the halogen-containing pre-clean material to expose the silicon on the surface. A passivation film is deposited on the exposed silicon. The passivation film may include chlorine. The passivation film may prevent contamination of the silicon surface by chemical species from the later sublimation, which may be at a higher temperature than the earlier sublimation. Subsequently, a remaining portion of the halogen-containing pre-clean material and the passivation film are sublimated. A target material, such as a conductive material, may subsequently be deposited on the substrate surface.

A method of integrated circuit fabrication creating copper interconnect structures wherein the formation of copper oxide is reduced or eliminated by etching away the copper oxide performing an H2 plasma treatment in a plasma enhanced chemical vapor deposition chamber.

A method of forming a tantalum-nitride layer (204) for integrated circuit fabrication is disclosed. Alternating or co-reacting pulses of a tantalum containing precursor and a nitrogen containing precursor are provided to a chamber (100) to form layers (305, 307) of tantalum and nitrogen. The nitrogen precursor may be a plasma gas source. The resultant tantalum-nitride layer (204) may be used, for example, as a barrier layer. As barrier layers may be used with metal interconnect structures (206), at least one plasma anneal on the tantalum-nitride layer may be performed to reduce its resistivity and to improve film property.

A method for electrically testing a semiconductor wafer during integrated-circuit fabrication process, the method including: (i) providing a scanning charged-particle microscope (SCPM), having a defined scanning plane and operative, while in any one mechanical state, to scan a surface in the scanning plane within a two-dimensional scanning window, which has a given maximum size; (ii) providing in association with any layer of the wafer, it being a test layer, one or more test structures, each test structure including normally conductive areas within a normally non-conductive background in one or more layers, which include said test layer, the conductive areas formed as one or more patterns; the patterns in said test layer include one or more clusters of mutually isolated pads; each pad is conductively connected with a corresponding distinct point on the patterns and all the pads in any one cluster are sized and arranged so that at least a significant portion of each pad falls within a common window whose size does not exceed said maximum size of said scanning window; (iii) with said test layer forming the top surface of the wafer, placing the wafer on the SCPM and adjusting the mechanical state of the SCPM so that at least a significant portion of each pad in any one of said clusters is within said scanning window; (iv) causing the SCPM, while in said mechanical state, to scan all of the pads of said one cluster and thereby to provide information about the electrical state of the respective test structure.

Systems and methods for placement of dummy metal fills while preventing disturbance of device matching and optionally limiting capacitance increase are disclosed. A computer-automated method for locating dummy fills in an integrated circuit fabrication process generally comprises receiving an input layout of the integrated circuit and specification of device matching for the integrated circuit and locating the dummy fills in the integrated circuit according to dummy rules while preserving device matching. Locating the dummy fills may include locating the dummy fills along the at least one axis of symmetry where device matching is along an axis of symmetry and locating the dummy fills so as to preserve matching of the repeated elements where device matching is repeated matched elements. The method may also include designating at least one net of the integrated circuit as a critical net, the critical nets being only a subset of all nets of the integrated circuit, identifying metal conductors corresponding to each designated critical net from the layout file, and delineating a net blocking exclusion zone extending a distance of a minimum net blocking distance (NBD) from the metal conductor for each metal conductor identified, wherein the step of locating locates the dummy fills outside of the net blocking exclusion zone.

There are many inventions described and illustrated herein. In one aspect, the present invention is directed to a technique of, and system for autonomously monitoring fabrication equipment, for example, integrated circuit fabrication equipment. In one embodiment of this aspect of the invention, the present invention is an autonomous monitoring device including one or more event sensors (for example, acceleration, motion, velocity and / or inertial sensing device(s)) to detect a predetermined event of or by the fabrication equipment (for example, an event that is indicative of the onset, commencement, initiation and / or launch of fabrication process or sub-processes of or by the fabrication equipment). In response thereto, one or more process parameter sensors sample, sense, detect, characterize, analyze and / or inspect one or more parameters of the process in real time (i.e., during the fabrication process).

Methods for removing a passivation film from a copper surface can include exposing the passivation film to a vapor phase organic reactant, for example at a temperature of 100° C. to 400° C. In some embodiments, the passivation film may have been formed by exposure of the copper surface to benzotriazole, such as can occur during a chemical mechanical planarization process. The methods can be performed as part of a process for integrated circuit fabrication. A second material can be selectively deposited on the cleaned copper surface relative to another surface of the substrate.