Abstract: A system for removing particles from a polishing pad to improve the efficiency of the removal of material by the polishing pad as part of a chemical-mechanical polishing process, the system comprising a polishing pad; a fluid dispenser arranged to dispense a fluid on the polishing pad; and removal means, wherein the removal means include a heater for increasing the temperature of the fluid dispensed on the polishing pad, and/or voltage means for coupling the polishing pad to a voltage source for repelling charged particles from the polishing pad surface while the fluid dispenser is dispensing the fluid on the polishing pad.

Abstract: Silicon wafers and the like are cleaned using new scrubber-type apparatus in which measures are taken to compensate for differential cleaning of the central region of the wafer by: using rotary brushes having one or more non-contact portions arranged in the section thereof that faces the central region of the substrate, or toggling the relative position of the wafer and the rotary brushes, or directing cleaning fluid(s) preferentially towards the central region of the wafer. Another aspect of the invention provides scrubber-type cleaning apparatus in which the rotary brushes are replaced by rollers (110). A web of cleaning material (116) is interposed between each roller and the substrate. Various different webs of cleaning material may be used, e.g. a length of tissue, a continuous loop of cleaning material whose surface is reconditioned on each cleaning pass, adhesive material provided on a carrier tape, etc.

Abstract: A process for the formation of a capping layer on a conducting interconnect for a semiconductor device is provided, the process comprising the steps of: (a) providing one or more conductors in a dielectric layer, and (b) depositing a capping layer on an upper surface of at least some of the one or more conductors, characterised in that the process further includes: (c) the step of, prior to depositing the capping layer, reacting the dielectric layer with an organic compound in a liquid phase, the said organic compound having the following general formula: (I) where X is a functional group, R is an organic group or a organosiloxane group, Y1 is either a functional group or an organic group or organosiloxane group, and Y2 is either a functional group or an organic group or organosiloxane group, and where the functional group(s) is/are independently selected from the following: NH2, a secondary amine, a tertiary amine, acetamide, trifluoroacetamide, imidazole, urea, OH, an alkyoxy, acryloxy, acetate, SH, an alky

Abstract: A passivating coupling material for, on the one hand, passivating a dielectric layer in a semiconductor device, and on the other hand, for permitting or at least promoting liquid phase metal deposition thereon in a subsequent process step. In a particular example, the dielectric layer may be a porous material having a desirably decreased dielectric constant k, and the passivating coupling material provides steric shielding groups that substantially block the adsorption and uptake of ambient moisture into the porous dielectric layer. The passivating coupling materials also provides metal nucleation sides for promoting the deposition of a metal thereon in liquid phase, in comparison with metal deposition without the presence of the passivating coupling material. The use of a liquid phase metal deposition process facilitates the subsequent manufacture of the semiconductor device.

Abstract: A process for fabricating an integrated electrical circuit comprises the formation and then the removal of conducting inserts. Components of the electrical circuit are incorporated into insulating materials superposed on top of a substrate. The process makes it possible to provide an exclusion volume around certain components sensitive to electrostatic coupling, while giving each insulating material a planar surface at the end of a polishing step.

Abstract: An electrical connection device between two conducting tracks of an integrated circuit comprises a first conducting connection between the two tracks. The device further comprises an additional interface of one of the two tracks, different from the interface of the track with the first connection and different from the lateral interface of the track with an insulating material parallel to the flow direction of the electric current in the track. The additional interface is placed at some distance from the first connection which is substantially less than the width of the track. The additional interface may be obtained by placing at least a second conducting connection between the two tracks, or by placing at least one rib in the track, or by placing notches on at least one of the faces of the track.

Abstract: An electrical connection device between two conducting tracks of an integrated circuit comprises a first conducting connection between the two tracks. The device further comprises an additional interface of one of the two tracks, different from the interface of the track with the first connection and different from the lateral interface of the track with an insulating material parallel to the flow direction of the electric current in the track. The additional interface is placed at some distance from the first connection which is substantially less than the width of the track. The additional interface may be obtained by placing at least a second conducting connection between the two tracks, or by placing at least one rib in the track, or by placing notches on at least one of the faces of the track.

Abstract: A process for fabricating an integrated electrical circuit comprises the formation and then the removal of conducting inserts. Components of the electrical circuit are incorporated into insulating materials superposed on top of a substrate. The process makes it possible to provide an exclusion volume around certain components sensitive to electrostatic coupling, while giving each insulating material a planar surface at the end of a polishing step.

Abstract: A process produces at a predetermined metallization level at least one metal track (7) within an intertrack dielectric material (1). The process includes the steps of etching the intertrack dielectric material (1) so as to form a cavity (4) at the position of the track, depositing a conducting barrier layer (5) in the cavity (4), filling the cavity (4) with copper, and depositing a silicon nitride layer (8) on the predetermined metallization level. Between the barrier layer deposition step and the copper filling step, titanium is deposited on at least part of the barrier layer. This titanium will be transformed into TiSi2 (60) during the diffusion of the silicon from the silicon nitride layer (8).

Abstract: A semiconductor device, for example an IC, having conductor tracks (3) of a metal (3) exhibiting a better conductance than aluminium, such as copper, silver, gold or an alloy thereof. The tracks are situated on an insulating layer (2) and are connected to a semiconductor region (1A) or to an aluminium conductor track by means of a metal plug (5), for example of tungsten, which is situated in an aperture (4) in the insulating layer (2). The bottom and walls of the aperture (4) are provided with an electroconductive material (6), such as titanium nitride, which forms a diffusion barrier for the metal (3). In accordance with the invention, the insulating layer (2) comprises a sub-layer (2A), which forms a diffusion barrier for the metal (3) and which extends, outside the aperture (4), throughout the surface of the semiconductor body (10). As a result, the conductor tracks (3) no longer have to be provided with a sheath serving as a diffusion barrier for the metal (3).