Abstract: A microelectronic substrate and method for removing adjacent conductive and nonconductive materials from a microelectronic substrate. In one embodiment, the microelectronic substrate includes a substrate material (such as borophosphosilicate glass) having an aperture with a conductive material (such as platinum) disposed in the aperture and a fill material (such as phosphosilicate glass) in the aperture adjacent to the conductive material. The fill material can have a hardness of about 0.04 GPa or higher, and a microelectronics structure, such as an electrode, can be disposed in the aperture, for example, after removing the fill material from the aperture. Portions of the conductive and fill material external to the aperture can be removed by chemically-mechanically polishing the fill material, recessing the fill material inwardly from the conductive material, and electrochemically-mechanically polishing the conductive material.

Abstract: An apparatus for performing a global planarization of a surface of a deformable layer of a wafer on a production scale. The apparatus includes a chamber having a pressing surface and containing a rigid plate and a flexible pressing member or “puck” disposed between the rigid plate and the pressing surface. A wafer having a deformable outermost layer is placed on the flexible pressing member so the deformable layer of the wafer is directly opposite and substantially parallel to the pressing surface. Force is applied to the rigid plate which propagates through the flexible pressing member to press the deformable layer of the wafer against the pressing surface. Preferably, a bellows arrangement is used to ensure a uniformly applied force to the rigid plate. The flexible puck serves to provide a self adjusting mode of uniformly distributing the applied force to the wafer, ensuring the formation of a high quality planar surface.

Abstract: A permanent protective semiconductor die coating made from a polymer that is fully curable through exposure to ultra violet light. A mixture of polymer resin and a photoactive compound is applied to the die and then cured through exposure to ultraviolet light to form the protective coating. In one preferred embodiment, the polymer resin is a phenol-formaldehyde epoxy resin and the photoactive compound is CD1011 (marketed under the brand name SARTOMER”. The coating may be applied as a thin protective film, such as a passivation layer, or as a thicker encapsulant used for semiconductor device packages. Such film coatings exhibit reduced film shrinkage and lower film stresses while maintaining mechanical properties comparable to polyimide film coatings.

Abstract: In a double metal process for forming conductive contacts to integrated circuit structures, a method for preventing the sputtering of non-conductive aluminum compounds onto via sidewalls during the anisotropic oxide etch. A layer of nitride is deposited atop aluminum buried first metal pads before deposited of the silicon dioxide layer. A selective anisotropic oxide etch which selectively stops on the nitride is used to form the via through the oxide layer. Then an isotropic low-powered dry nitride etch extends the via through the nitride to the aluminum pad without producing unwanted sputtering.

Abstract: The invention encompasses methods of forming insulating materials between conductive elements. In one aspect, the invention includes a method of forming a material adjacent a conductive electrical component comprising: a) partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. In another aspect, the invention includes a method of forming a material between a pair of conductive electrical components comprising the following steps: a) forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; b) forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and c) vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components.

Abstract: A method for controlling the voltage distribution of the standing wave impressed upon the coil of an inductively coupled plasma generator includes the steps of impressing a radio frequency voltage across the coil to establish a standing wave thereacross. A voltage profile is selected for the standing wave so as to control the location and amount of capacitive coupling. A circuit parameter is controlled to achieve the selected voltage profile. Proper selection of the voltage profile enhances process capabilities, decreases the time between cleans, minimizes component wear, and minimizes cleaning time. An apparatus for carrying out the disclosed method is also disclosed.

Abstract: A method for controlling the voltage distribution of the standing wave impressed upon the coil of an inductively coupled plasma generator includes the steps of impressing a radio frequency voltage across the coil to establish a standing wave thereacross. A voltage profile is selected for the standing wave so as to control the location and amount of capacitive coupling. A circuit parameter is controlled to achieve the selected voltage profile. Proper selection of the voltage profile enhances process capabilities, decreases the time between cleans, minimizes component wear, and minimizes cleaning time. An apparatus for carrying out the disclosed method is also disclosed.

Abstract: The invention encompasses methods of forming insulating materials between conductive elements. In one aspect, the invention includes a method of forming a material adjacent a conductive electrical component comprising: a) partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. In another aspect, the invention includes a method of forming a material between a pair of conductive electrical components comprising the following steps: a) forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; b) forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and c) vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components.

Abstract: A method of forming a connection is comprised of the steps of depositing a lower conductor. A dielectric layer is deposited on the lower conductor, with the dielectric layer having a lower surface adjacent to the lower conductor, and having an upper surface. An opening extending between the upper surface and the lower surface of the dielectric layer is formed. A conductive plug is deposited within the opening, with the plug having an upper surface proximate the upper surface of the dielectric layer. The upper surface has an edge where the upper surface of the plug is adjacent to the dielectric layer. A recess is formed proximate to the edge of the upper surface of the plug, the recess extending into both the plug and the dielectric layer. Finally, an upper conductor is deposited on the upper surface of the dielectric layer and the upper surface of the plug. A connection thus formed is also disclosed.

Abstract: A method of forming a connection is comprised of the steps of depositing a lower conductor. A dielectric layer is deposited on the lower conductor, with the dielectric layer having a lower surface adjacent to the lower conductor, and having an upper surface. An opening extending between the upper surface and the lower surface of the dielectric layer is formed. A conductive plug is deposited within the opening, with the plug having an upper surface proximate the upper surface of the dielectric layer. The upper surface has an edge where the upper surface of the plug is adjacent to the dielectric layer. A recess is formed proximate to the edge of the upper surface of the plug, the recess extending into both the plug and the dielectric layer. Finally, an upper conductor is deposited on the upper surface of the dielectric layer and the upper surface of the plug. A connection thus formed is also disclosed.

Abstract: A method of forming a connection is comprised of the steps of depositing a lower conductor. A dielectric layer is deposited on the lower conductor, with the dielectric layer having a lower surface adjacent to the lower conductor, and having an upper surface. An opening extending between the upper surface and the lower surface of the dielectric layer is formed. A conductive plug is deposited within the opening, with the plug having an upper surface proximate the upper surface of the dielectric layer. The upper surface has an edge where the upper surface of the plug is adjacent to the dielectric layer. A recess is formed proximate to the edge of the upper surface of the plug, the recess extending into both the plug and the dielectric layer. Finally, an upper conductor is deposited on the upper surface of the dielectric layer and the upper surface of the plug. A connection thus formed is also disclosed.

Abstract: A permanent protective semiconductor die coating made from a polymer that is fully curable through exposure to ultra violet light. A mixture of polymer resin and a photoactive compound is applied to the die and then cured through exposure to ultraviolet light to form the protective coating. In one preferred embodiment, the polymer resin is a phenol-formaldehyde epoxy resin and the photoactive compound is CD1011 (marketed under the brand name SARTOMER”. The coating may be applied as a thin protective film, such as a passivation layer, or as a thicker encapsulant used for semiconductor device packages. Such film coatings exhibit reduced film shrinkage and lower film stresses while maintaining mechanical properties comparable to polyimide film coatings.

Abstract: A method of constructing a conductive via spacer within a dielectric layer located between a first metal layer and a second metal layer includes the steps of depositing a conductive spacer layer within the opening and over the first metal layer. A portion of the conductive spacer layer is removed to leave a conductive spacer within the opening. The second metal layer is deposited over the spacer to complete the connection between the first and second metal layers. The spacer preferably comprises a material selected from the group comprising refractory metal silicides and nitrides. The spacer is preferably tapered and the via may include a glue layer to improve the adherence of the spacer to the dielectric layer.

Abstract: A method for removing a surface defect from a dielectric layer during the formation of a semiconductor device comprises the steps of forming a dielectric layer having a hole therein, the dielectric also having a surface defect resulting from a previous manufacturing step such as chemical mechanical polish, contact with another surface during production, or from a manufacturing defect. A blanket conductive layer is then formed within the hole, within the surface defect, and over the dielectric layer. The conductive layer is etched from the surface of the dielectric using an etch which removes the conductive layer at a substantially faster rate than it removes the dielectric. This etch is stopped when the level of conductive material in the plug is flush with the upper surface of the dielectric. Next, the conductive and dielectric layers are etched using a dry or plasma etch which removes the conductive and dielectric layers at about the same rate.

Abstract: A method of constructing a conductive via spacer within a dielectric layer located between a first metal layer and a second metal layer includes the steps of depositing a conductive spacer layer within the opening and over the first metal layer. A portion of the conductive spacer layer is removed to leave a conductive spacer within the opening. The second metal layer is deposited over the spacer to complete the connection between the first and second metal layers. The spacer preferably comprises a material selected from the group comprising refractory metal silicides and nitrides. The spacer is preferably tapered and the via may include a glue layer to improve the adherence of the spacer to the dielectric layer.

Abstract: The invention encompasses methods of forming insulating materials between conductive elements. In one aspect, the invention includes a method of forming a material adjacent a conductive electrical component comprising: a) partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. In another aspect, the invention includes a method of forming a material between a pair of conductive electrical components comprising the following steps: a) forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; b) forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and c) vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components.

Abstract: The invention encompasses methods of forming insulating materials between conductive elements. In one aspect, the invention includes a method of forming a material adjacent a conductive electrical component comprising: a) partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. In another aspect, the invention includes a method of forming a material between a pair of conductive electrical components comprising the following steps: a) forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; b) forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and c) vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components.

Abstract: The invention encompasses methods of forming insulating materials between conductive elements. In one aspect, the invention includes a method of forming a material adjacent a conductive electrical component comprising: a) partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. In another aspect, the invention includes a method of forming a material between a pair of conductive electrical components comprising the following steps: a) forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; b) forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and c) vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components.

Abstract: A method of forming a connection is comprised of the steps of depositing a lower conductor. A dielectric layer is deposited on the lower conductor, with the dielectric layer having a lower surface adjacent to the lower conductor, and having an upper surface. An opening extending between the upper surface and the lower surface of the dielectric layer is formed. A conductive plug is deposited within the opening, with the plug having an upper surface proximate the upper surface of the dielectric layer. The upper surface has an edge where the upper surface of the plug is adjacent to the dielectric layer. A recess is formed proximate to the edge of the upper surface of the plug, the recess extending into both the plug and the dielectric layer. Finally, an upper conductor is deposited on the upper surface of the dielectric layer and the upper surface of the plug. A connection thus formed is also disclosed.

Abstract: A method of forming a capacitor on a semiconductor wafer includes: a) in a dry etching reactor, selectively anisotropically dry etching a capacitor contact opening having a minimum selected open dimension into an insulating dielectric layer utilizing selected gas flow rates of a reactive gas component and an inert gas bombarding component, the flow rate of the bombarding component significantly exceeding the flow rate of the reactive component to effectively produce a capacitor contact opening having grooved striated sidewalls and thereby defining female capacitor contact opening striations; b) providing a layer of an electrically conductive storage node material within the striated capacitor contact opening; c) removing at least a portion of the conductive material layer to define an isolated capacitor storage node within the insulating dielectric having striated sidewalls; d) etching the insulating dielectric layer selectively relative to the conductive material sufficiently to expose at least a portion of