Abstract: A method is disclosed for the production of thick and smooth layers of photoresist on the order of 2-15 microns thick. The substrate is flooded with resist as in the standard spin resist method, but instead of following the flooding step with spinning as usual, the second step is to provide a drying time for the flooded resist. Then at the end of the measured drying time, the resist is spun as usual. This can be used to produce fine line closely spaced circuitry in which the thickness of the lines in proportion to their width, or their aspect ratio, is large. Aspect ratios greater than 0.4 and as high as 1.5 are contemplated by the invention.

Abstract: Resist is applied to a surface with a syringe, or other suitable dropper, equipped with a millipore filter to remove contaminants. The surface is completely flooded with resist. Resist is allowed to remain on the surface of the evaporated metal for a period of time prior to spin coating. Allowing resist to remain on the surface prior to coating produces a uniform film. For a 2 micron thick uniform resist coating, a minimum of 15 seconds is allowed prior to spinning while in the case of a 4 micron thick resist coating a much longer period is allowed.For the application of a 2 micron film, the resist material after partial drying for approximately 15 seconds is spun at 2000 rpm for 30 seconds. In order to apply a 5 micron thick resist film, resist is spun at 2000 rpm for 30 seconds after partial drying for approximately 10 minutes.

Abstract: A method of constructing a relatively thick, self-supporting mask suitable for electron beam projection processes. Thickness is achieved by multiple steps of coating with resist, exposure, development and plating. First an intermediate or lift off layer is deposited on a substrate. A plating or a cathode layer may then be deposited. Resist is then applied. A first mask layer comprises metal plated in accordance with the first pattern. For the second exposure a geometrically similar pattern is employed to generate larger apertures. Thus, if the first mask layer has 0.20 mil apertures, the second layer might have corresponding 0.21 mil to 0.22 mil apertures. For initial mask patterns of about 2 mil the second layer might be 2.02 mils. If desired, a third exposure can be employed with a third pattern, similar to the first two, but having larger apertures (by 0.02 to 0.03 mils) than the second pattern.

Abstract: A method for increasing the magnetic permeability of a magnetic alloy having an easy axis and a hard axis which comprises subjecting a body of the magnetic alloy to a magnetic field of at least about 40 Gauss oriented in the direction of the hard axis while the body is maintained at a temperature at or above that required to deposit the alloy on a substrate.