Abstract: A method of making an integrated circuit interconnect structure having air as the effective dielectric between metallization layers includes the steps of: a) providing an air dielectric formation layer of a sacrificial material over a substrate; b) forming a pillar holes in the air dielectric formation layer; c) filling the pillar holes with a non-sacrificial material; d) constructing a metallization layer over the sacrificial air dielectric formation layer and non-sacrificial material pillars; and e) applying an isotropic etchant to the interconnect structure to remove the sacrificial material, leaving the non-sacrificial material pillars for mechanical support of the metallization layer. An interconnect structure having an air dielectric includes a bottom metallization layer, a top metallization layer, and a plurality of pillars separating the bottom and top metallization layers and mechanically supporting the top metallization layer.

Abstract: Disclosed is a method for making a passivation coated semiconductor structure. The method includes providing a substrate having a metallization line patterned over the substrate. The metallization line defining at least one interconnect feature having a first thickness, and depositing a first silicon nitride barrier layer having a second thickness over the substrate and the metallization line. The method further including applying an oxide material over the first silicon nitride barrier layer that overlies the substrate and the metallization line. The oxide application includes a deposition component and a sputtering component, and the sputtering component is configured to remove at least a part of an edge of the first silicon nitride layer. The edge is defined by the metallization line underlying the first silicon nitride layer.

Abstract: A method for manufacturing arrays of field emission tips, suitable for use in field emission displays (FEDs), begins by depositing a conductive cathode layer over a substrate and then patterning the conductive cathode layer to define a set of cathode structures on which the array of tips are to be formed. A layer of a insulator material is deposited and then a layer of lift-off material is deposited. The lift-off material is capable of being selectively etched with respect to the insulator layer. The insulator material layer and lift-off material layer are patterned to define a set of apertures in which field emission tips are to be formed. Next, tip material is deposited using an unbiased high density plasma chemical vapor deposition (HDPCVD) process to form sharp field emission tips in the apertures. The HDPCVD process also forms a sacrificial layer of islands of tip material on top of the patterned layer of lift-off material.

Abstract: A method for manufacturing probe tips suitable for use in an atomic force microscope (AFM) or scanning tunneling microscope (STM) begins by depositing a layer of a first material over a substrate and then patterning the layer of the first material to define apertures wherever probe tips are to be formed. Next, a layer of a second material is deposited using an unbiased high density plasma chemical vapor deposition (HDPCVD) process to form sharp probe tips in the apertures in the layer of the first material. The HDPCVD process also forms a sacrificial layer of the second material on top of the portions of the first material not removed by the patterning step. The sacrificial layer at least partially overhangs the apertures in the first material, forming a shadow mask during the deposition process which gives rise to a sharp probe profile.

Abstract: Disclosed is a method for making a passivation coated semiconductor structure. The method includes providing a substrate having a metallization line patterned over the substrate. The metallization line defining at least one interconnect feature having a first thickness, and depositing a first silicon nitride barrier layer having a second thickness over the substrate and the metallization line. The method further including applying an oxide material over the first silicon nitride barrier layer that overlies the substrate and the metallization line. The oxide application includes a deposition component and a sputtering component, and the sputtering component is configured to remove at least a part of an edge of the first silicon nitride layer. The edge is defined by the metallization line underlying the first silicon nitride layer.

Abstract: A method of making an integrated circuit interconnect structure having air as the effective dielectric between metallization layers includes the steps of: a) providing an air dielectric formation layer of a sacrificial material over a substrate; b) forming a pillar holes in the air dielectric formation layer; c) filling the pillar holes with a non-sacrificial material; d) constructing a metallization layer over the sacrificial air dielectric formation layer and nonsacrificial material pillars; and e) applying an isotropic etchant to the interconnect structure to remove the sacrificial material, leaving the non-sacrificial material pillars for mechanical support of the metallization layer. An interconnect structure having an air dielectric includes a bottom metallization layer, a top metallization layer, and a plurality of pillars separating the bottom and top metallization layers and mechanically supporting the top metallization layer.

Abstract: A scanning tunneling optical spectrometer, and corresponding method, for measuring spectral response of a tunneling probe-sample junction over the range of optical frequencies enabling determination of characteristics of and imaging of subsurface structures with nanometer resolutions. A tunneling probe is positioned adjacent the sample with a bias voltage applied and an optical source is employed to direct modulated optical radiation onto the sample probe junction to generate photoexcited tunneling current without interference from tunneling current variations caused by thermal heating by the optical radiation. The optical source is frequency scanned over a selected frequency range and the photoexcited tunneling current is detected employing phase detection thereby permitting measurement of properties of such materials as semiconductors, buried semiconductor structures, and other organic or inorganic photoconductors.