Abstract: A memory circuit is provided with a spacer formed on a support surface and positioned adjacent to a first electrode surface of a first electrode. The memory circuit further includes a ferroelectric layer formed on the first electrode and the spacer.

Abstract: Embodiments in accordance with the present invention eliminate the need for a subtractive metal patterning process to pattern the electrode above a ferroelectric polymer. Instead, a selective electroless deposition process is used. A conductive polymer is used as a seed layer for the electroless plating of the metal electrode. A cost saving is provided by eliminating the chemical costs associated with conventional resist removal processing. The methods also potentially eliminate the requirement for aggressive and environmentally unsafe chemical-based photoresist removal processes.

Abstract: The present invention describes a method for creating a differential polish rate across a semiconductor wafer. The profile or topography of the semiconductor wafer is determined by locating the high points and low points of the wafer profile. The groove pattern of a polish pad is then adjusted to optimize the polish rate with respect to the particular wafer profile. By increasing the groove depth, width, and/or density of the groove pattern of the polish pad the polish rate may be increased in the areas that correspond to the high points of the wafer profile. By decreasing the groove depth, width, and/or density of the groove pattern of the polish pad the polish rate may be decreased in the areas that correspond to the low points of the wafer profile. A combination of these effects may be desirable in order to stabilize the polish rate across the wafer surface in order to improve the planarization of the polishing process.

Abstract: A process for forming an interlayer dielectric layer is disclosed. The method comprises first forming a carbon-doped oxide (CDO) layer with a first concentration of carbon dopants therein. Next, the CDO layer is further formed with a second concentration of carbon dopants therein, wherein the first concentration is different than the second concentration.

Abstract: By using a plurality of relatively thin stacked diffusion layers interposed between a conductive line and a polymer layer, the diffusion of contaminates into a polymer layer from the conductive line may be reduced. This may reduce part failure during fatigue or disturb testing, for example, in ferroelectric polymer memories.

Abstract: Methods of depositing various metal layers adjacent to a ferroelectric polymer layer are disclosed. In one embodiment, a collimator may be used during a sputtering process to filter out charged particles from the material that may be deposited as a metal layer. In various embodiments, a metal layer may contain at least one of an intermetallic layer, an amorphous intermetallic layer, and an amorphized intermetallic layer.

Abstract: An improved semiconductor device is described. That semiconductor device includes a first insulating layer, having a low-k dielectric constant that preferably comprises a carbon doped oxide, that is formed on a substrate. The device further includes a second layer, which is formed on the first layer, that has a relatively high dielectric constant and superior mechanical strength. The second layer is preferably under compressive stress. A third layer may be formed on the second layer, which has a relatively low dielectric constant and relatively poor mechanical strength, and a fourth layer may be formed on the third layer, which has a relatively high dielectric constant and superior mechanical strength.

Abstract: An electrode layer for a polymer memory may be implanted to increase the number of defects in the material. As a result, that same material may be utilized for the upper and lower electrodes. In particular, defects may be introduced into a TiOx layer within the electrode to match the work functions of the upper and lower electrodes.

Abstract: Embodiments of the invention provide a method for producing ferroelectric polymer devices (FPMDs) employing conditions that avoid or reduce detrimental impact on the ferroelectric polymer film. For one embodiment, a damascene patterning metallization technique is used. For one embodiment a first metal layer is deposited on a substrate to form the bottom electrode for the FPMD. The first metal layer is capped with a selectively deposited diffusion barrier. A layer of ferroelectric polymer film is then deposited on the first conductive layer. The ferroelectric polymer film is planarized. A second metal layer is deposited on the ferroelectric polymer film layer to form the top electrode of the FPMD. The second metal layer is deposited such that the ferroelectric polymer film is not substantially degraded. For various alternative embodiments the various component processes may be accomplished at temperatures far below those employed in a conventional damascene patterning metallization process.

Abstract: Methods for improving the net remnant polarization of a polymer memory cell are disclosed. In one embodiment, the polymer material is heated above the Curie temperature of the polymer material, and the domains of the polymer material are aligned with an externally applied electric field.

Abstract: According to one aspect of the invention, a memory array and a method of constructing a memory array are provided. An insulating layer is formed on a semiconductor substrate. A first metal stack is then formed on the insulating layer. The first metal stack is etched to form first metal lines. A polymeric layer is formed over the first metal lines and the insulating layer. The polymeric layer has a surface with a plurality of roughness formations. A second metal stack is formed on the polymeric layer with an interface layer, which is thicker than the heights of the roughness formations. Then the second metal stack is etched to form second metal lines. Memory cells are formed wherever a second metal line extends over a first metal line.

Abstract: A series of address lines extend in a first direction through at least two layers of memory material spaced apart in the first direction. The memory material may be a ferroelectric polymer in one embodiment. The arrangement of lines and layers may increase the density of a memory in one embodiment.

Abstract: Embodiments in accordance with the present invention eliminate the need for a subtractive metal patterning process to pattern the electrode above a ferroelectric polymer. Instead, a selective electroless deposition process is used. A conductive polymer is used as a seed layer for the electroless plating of the metal electrode. A cost saving is provided by eliminating the chemical costs associated with conventional resist removal processing. The methods also potentially eliminate the requirement for aggressive and environmentally unsafe chemical-based photoresist removal processes.

Abstract: A process for forming an interlayer dielectric layer is disclosed. The method comprises first forming a carbon-doped oxide (CDO) layer with a first concentration of carbon dopants therein. Next, the CDO layer is further formed with a second concentration of carbon dopants therein, wherein the first concentration is different than the second concentration.

Abstract: Embodiments of the invention provide a method for producing ferroelectric polymer devices (FPMDs) employing conditions that avoid or reduce detrimental impact on the ferroelectric polymer film. For one embodiment, a damascene patterning metallization technique is used. For one embodiment a first metal layer is deposited on a substrate to form the bottom electrode for the FPMD. The first metal layer is capped with a selectively deposited diffusion barrier. A layer of ferroelectric polymer film is then deposited on the first conductive layer. The ferroelectric polymer film is planarized. A second metal layer is deposited on the ferroelectric polymer film layer to form the top electrode of the FPMD. The second metal layer is deposited such that the ferroelectric polymer film is not substantially degraded. For various alternative embodiments the various component processes may be accomplished at temperatures far below those employed in a conventional damascene patterning metallization process.

Abstract: Embodiments of the invention provide a method for producing ferroelectric polymer devices (FPMDs) employing conditions that avoid or reduce detrimental impact on the ferroelectric polymer film. For one embodiment, a damascene patterning metallization technique is used. For one embodiment a first metal layer is deposited on a substrate to form the bottom electrode for the FPMD. The first metal layer is capped with a selectively deposited diffusion barrier. A layer of ferroelectric polymer film is then deposited on the first conductive layer. The ferroelectric polymer film is planarized. A second metal layer is deposited on the ferroelectric polymer film layer to form the top electrode of the FPMD. The second metal layer is deposited such that the ferroelectric polymer film is not substantially degraded. For various alternative embodiments the various component processes may be accomplished at temperatures far below those employed in a conventional damascene patterning metallization process.

Abstract: According to one aspect of the invention, a method of constructing a memory array is provided. An insulating layer is formed on a semiconductor wafer. A first metal stack is then formed on the insulating layer and etched to form first metal lines. A polymeric layer is formed over the first metal lines and the insulating layer. A puddle of smoothing solvent is then allowed to stand on the wafer. The smoothing solvent is then removed. After the smoothing solvent is removed, the polymeric layer has a reduced surface roughness. A second metal stack is then formed on the polymeric layer and etched to form second metal lines.

Abstract: According to one aspect of the invention, a memory array and a method of constructing a memory array are provided. An insulating layer is formed on a semiconductor substrate. A first metal stack is then formed on the insulating layer. The first metal stack is etched to form first metal lines. A polymeric layer is formed over the first metal lines and the insulating layer. The polymeric layer has a surface with a plurality of roughness formations. A second metal stack is formed on the polymeric layer with an interface layer, which is thicker than the heights of the roughness formations. Then the second metal stack is etched to form second metal lines. Memory cells are formed wherever a second metal line extends over a first metal line.

Abstract: A low dielectric constant material having a first fluorine concentration in a near-surface portion and a second fluorine concentration in an interior portion provides an insulator suitable for use in integrated circuits. In a further aspect of the present invention, fluorine is depleted from a near-surface portion of a fluorine containing dielectric material by a reducing plasma. Fluorine in fluorinated low-k dielectric materials, such as SiOF, amorphous fluorinated carbon (a-F:C) and parylene-AF4, can react with surrounding materials such as metals and Si3N4, causing blisters and delamination. Treatment of these fluorinated low-k dielectric materials in a reducing plasma, which may be produced from precursor gases such as H2 or NH3, depletes the surface region of fluorine and hence reduces reaction with surrounding materials and F outgassing. By selecting an appropriate point in the integration flow, specific interfaces which are most susceptible to F-attack can be targeted for depletion.

Abstract: A ferroelectric memory device and a method of formation are disclosed. In one particular embodiment, a ferroelectric memory device comprises a first electrode layer formed on a substrate, a ferroelectric polymer layer formed on substantial portion of a first electrode layer, a thin layer of conductive ferroelectric polymer formed on a substantial portion of the ferroelectric polymer layer, where the ferroelectric polymer may be made conductive by doping with conductive nano-particles, and a second electrode layer formed on at least a portion of the carbon doped ferroelectric polymer layer.