Abstract: The present invention is directed to an alpha-W layer which is employed in interconnect structures such as trench capacitors or damascene wiring levels as a diffusion barrier layer. The alpha-W layer is a single phased material that is formed by a low temperature/pressure chemical vapor deposition process using tungsten hexacarbonyl, W(CO)6, as the source material.

Abstract: A semiconductor device containing a diffusion barrier layer is provided. The semiconductor device includes at least a semiconductor substrate containing conductive metal elements; and, a diffusion barrier layer applied to at least a portion of the substrate in contact with the conductive metal elements, the diffusion barrier layer having an upper surface and a lower surface and a central portion, and being formed from silicon, carbon, nitrogen and hydrogen with the nitrogen being non-uniformly distributed throughout the diffusion barrier layer. Thus, the nitrogen is more concentrated near the lower and upper surfaces of the diffusion barrier layer as compared to the central portion of the diffusion barrier layer. Methods for making the semiconductor devices are also provided.

Abstract: An interlayer dielectric for preventing Cu ion migration in semiconductor structure containing a Cu region is provided. The interlayer dielectric of the present invention comprises a dielectric material that has a dielectric constant of 3.0 or less and an additive which is highly-capable of binding Cu ions, yet is soluble in the dielectric material. The presence of the additive in the low k dielectric allows for the elimination of conventional inorganic barrier materials such as SiO2 or Si3N4.

Abstract: A uniformly thick oxide film on a substrate is formed by using an anodization apparatus which deposits a blanket precursor film on a surface of a substrate; provides electrical contact to the precursor film; moves the precursor film into contact with an electrolyte solution such that substantially all electrically conductive surfaces, e.g., pin contacts, the substrate edge and a backside of the substrate are electrically isolated from the electrolyte; ensures that the surface of the precursor film on the substrate is in direct contact with the electrolyte solution; and which applies an anodizing current and/or voltage between the precursor film and a counter electrode so as to compensate for a voltage drop resulting from the presence of the electrolyte.

Abstract: The present invention includes a multilevel air-gap-containing interconnect wiring structure including: a collection of interspersed line levels and via levels, the via levels and line levels containing conductive via and line features embedded in a dielectric having an air-gap and solid dielectric. The air-gap and solid dielectric includes (i) one or more solid dielectrics only in the shadows of the conductive features in overlying levels and (ii) a gaseous dielectric elsewhere in the structure. The collection of line levels and via levels are topped by a laminated thin, taut insulating cover layer having openings to selected conductive features in the topmost underlying line or via layer, and the openings are filled with conductive material connecting to terminal pad contacts on the insulating cover layer.

Abstract: An insulator for covering an interconnection wiring level in a surface thereof on a semiconductor substrate containing semiconductor devices formed by curing a flowable oxide layer and annealing. The annealing is carried out in the presence of hydrogen and aluminum to obtain a dielectric constant of the oxide layer to a value below 3.2. Also provided is electrical insulation between neighboring devices using the flowable oxide which is cured and annealed. In this case, the annealing can be carried out in hydrogen with or without the presence of aluminum.

Abstract: An over voltage spike or surge protection principle is provided that involves an element that is positioned between a node in the circuitry and a reference voltage that performs as an insulator as voltage across the element increases and at a selectable voltage, the current at any higher voltage such as during a spike or a surge is shunted to reference or ground, the element is not damaged by the breakdown type of the effect of the shunting of the current, and then, after the duration of the high voltage excursion the element returns to the performance before the selectable voltage. The principle of the invention permits in-situ or locallized over voltage protection to selected nodes throughout circuitry as well as throughout an integrated circuit including the interface with external circuitry.

Abstract: The present invention is directed to an alpha-W layer which is employed in interconnect structures such as trench capacitors or damascene wiring levels as a diffusion barrier layer. The alpha-W layer is a single phased material that is formed by a low temperature/pressure chemical vapor deposition process using tungsten hexacarbonyl, W(CO)6, as the source material.

Abstract: An interlayer dielectric for preventing Cu ion migration in semiconductor structure containing a Cu region is provided. The interlayer dielectric of the present invention comprises a dielectric material that has a dielectric constant of 3.0 or less and an additive which is highly-capable of binding Cu ions, yet is soluble in the dielectric material. The presence of the additive in the low k dielectric allows for the elimination of conventional inorganic barrier materials such as SiO2 or Si3N4.

Abstract: An interlayer dielectric for preventing Cu ion migration in semiconductor structure containing a Cu region is provided. The interlayer dielectric of the present invention comprises a dielectric material that has a dielectric constant of 3.0 or less and an additive which is highly-capable of binding Cu ions, yet is soluble in the dielectric material. The presence of the additive in the low k dielectric allows for the elimination of conventional inorganic barrier materials such as SiO2 or Si3N4.

Abstract: An interlayer dielectric for preventing Cu ion migration in semiconductor structure containing a Cu region is provided. The interlayer dielectric of the present invention comprises a dielectric material that has a dielectric constant of 3.0 or less and an additive which is highly-capable of binding Cu ions, yet is soluble in the dielectric material. The presence of the additive in the low k dielectric allows for the elimination of conventional inorganic barrier materials such as SiO2 or Si3N4.

Abstract: A method to achieve a very low effective dielectric constant in high performance back end of the line chip interconnect wiring and the resulting multilayer structure are disclosed. The process involves fabricating the multilayer interconnect wiring structure by methods and materials currently known in the state of the art of semiconductor processing; removing the intralevel dielectric between the adjacent metal features by a suitable etching process; applying a thin passivation coating over the exposed etched structure; annealing the etched structure to remove plasma damage; laminating an insulating cover layer to the top surface of the passivated metal features; optionally depositing an insulating environmental barrier layer on top of the cover layer; etching vias in the environmental barrier layer, cover layer and the thin passivation layer for terminal pad contacts; and completing the device by fabricating terminal input/output pads.

Abstract: A composite dielectric material useful in advanced memory applications such as dynamic random access memory (DRAM) cells is provided. The composite dielectric material of the present invention includes a mixed oxide such as TiO.sub.2 or Ta.sub.2 O.sub.5 that is interdiffused into a Si.sub.3 N.sub.4 film. Capacitors including the composite dielectric material of the present invention are also disclosed.

Abstract: A method of fabricating a dielectric material useful in advanced memory applications which comprises a metal oxide such as TiO.sub.2 or Ta.sub.2 O.sub.5 interdiffused into a Si.sub.3 N.sub.4 film is provided.

Abstract: The present invention relates to semiconductor devices comprising as one of their structural components diamond-like carbon as an insulator for spacing apart one or more levels of a conductor on an integrated circuit chip. The present invention also relates to a method for forming an integrated structure and to the integrated structure produced therefrom. The present invention further provides a method for selectively ion etching a diamond-like carbon layer from a substrate containing such a layer.

Abstract: The present invention relates to semiconductor devices comprising as one of their structural components diamond-like carbon as an insulator for spacing apart one or more levels of a conductor on an integrated circuit chip. The present invention also relates to a method for forming an integrated structure and to the integrated structure produced therefrom. The present invention further provides a method for selectively ion etching a diamond-like carbon layer from a substrate containing such a layer.