Certain example embodiments relate to techniques for improving the uniformity of, and/or conformance to a desired pattern for, metal island layers (MILs) formed on a substrate (e.g., a glass or other substrate), and/or associated products. Certain example embodiments form MILs using a laser or other energy source or magnetic field assisted technique, e.g., to compensate for non-uniformities that otherwise likely would result in the MIL diverging from its desired configuration. For example, a laser or other energy source may introduce heat onto a substrate, enable pulsed laser deposition, raster a target including the MIL metal to be deposited, raster a substrate where the MIL is to be formed, etc. These and/or other techniques may be used to enable the MIL to be formed on the substrate in a desired pattern, e.g., by compensating for implicit non-uniformities of the substrate and/or by selectively creating non-uniformities in how the MIL is formed.

Certain example embodiments relate to techniques for improving the uniformity of, and/or conformance to a desired pattern for, metal island layers (MILs) formed on a substrate (e.g., a glass or other substrate), and/or associated products. Certain example embodiments form MILs using a laser or other energy source or magnetic field assisted technique, e.g., to compensate for non-uniformities that otherwise likely would result in the MIL diverging from its desired configuration. For example, a laser or other energy source may introduce heat onto a substrate, enable pulsed laser deposition, raster a target including the MIL metal to be deposited, raster a substrate where the MIL is to be formed, etc. These and/or other techniques may be used to enable the MIL to be formed on the substrate in a desired pattern, e.g., by compensating for implicit non-uniformities of the substrate and/or by selectively creating non-uniformities in how the MIL is formed.

A coated article is provided with at least one infrared (IR) reflecting layer. The IR reflecting layer may be of silver or the like. In certain example embodiments, a titanium oxide layer is provided over the IR reflecting layer, and it has been found that this surprisingly results in an IR reflecting layer with a lower specific resistivity (SR) thereby permitting thermal properties of the coated article to be improved.

A coated article is provided with at least one infrared (IR) reflecting layer. The IR reflecting layer may be of silver or the like. In certain example embodiments, a titanium oxide layer is provided over the IR reflecting layer, and it has been found that this surprisingly results in an IR reflecting layer with a lower specific resistivity (SR) thereby permitting thermal properties of the coated article to be improved.

A sputtering chamber includes at least two sputtering targets, one of the at least two targets disposed on a first side a substrate conveyor extending within the chamber, and another of the at least two targets disposed on a second side of the conveyor. The at least two targets may be independently operable, and at least one of the targets, if inactivated, may be protected by a shielding apparatus. Both of the at least two targets may be mounted to a first wall of a plurality of walls enclosing the sputtering chamber.

A method of manufacturing a component for a reference electrode assembly according to various aspects of the present disclosure includes providing a separator having first and second opposing surfaces. The method further includes sputtering a first current collector layer to the first surface via magnetron or ion beam sputtering deposition. A porosity of the separator is substantially unchanged by the sputtering. In one aspect, the method further includes sputtering a second current collector layer to the second surface via magnetron or ion beam sputtering deposition. In one aspect, the first current collector layer includes nickel and defines a first thickness of greater than or equal to about 200 nm to less than or equal to about 300 nm and the second current collector layer includes gold and defines a second thickness of greater than or equal to about 25 nm to less than or equal to about 100 nm.

Pallets for transporting one or more glass substrates in a substantially vertical orientation through a sputtering system. In some cases, a pallet comprising a frame with an aperture and an adjustable grid array within the aperture. The adjustable grid array is configurable to hold a plurality of glass substrates of different shapes and/or sizes. In one case, the adjustable grid array comprises a system of vertical and horizontal support bars, wherein the vertical support bars configured to both support the plurality of glass substrates at their vertical edges, wherein the horizontal support bars are configured to support the plurality of glass substrates at their horizontal edges, wherein the ends of the horizontal support bars are slideably engaged with the vertical support bars.

Pallets for transporting one or more glass substrates in a substantially vertical orientation through a sputtering system. In some cases, a pallet comprising a frame with an aperture and an adjustable grid array within the aperture. The adjustable grid array is configurable to hold a plurality of glass substrates of different shapes and/or sizes. In one case, the adjustable grid array comprises a system of vertical and horizontal support bars, wherein the vertical support bars configured to both support the plurality of glass substrates at their vertical edges, wherein the horizontal support bars are configured to support the plurality of glass substrates at their horizontal edges, wherein the ends of the horizontal support bars are slideably engaged with the vertical support bars.

A deposition system, and a method of operation thereof, includes: a cathode; a shroud below the cathode; a rotating shield below the cathode for exposing the cathode through the shroud and through a shield hole of the rotating shield; and a rotating pedestal for producing a material to form a carrier over the rotating pedestal, wherein the material having a non-uniformity constraint of less than 1% of a thickness of the material and the cathode having an angle between the cathode and the carrier.

The present disclosure provides methods of making and applying metalized graphene fibers in bioelectronics applications. For example, platinized graphene fibers may be used as an implantable conductive suture for neural and neuro-muscular interfaces in chronic applications. In some embodiments, an implantable electrode includes a multi-layer graphene-fiber core, an insulative coating surrounding the multi-layer graphene-fiber core, and a metal layer disposed between the multi-layer graphene-fiber core and the insulative coating.