Gmxxnet Article Submission
Magnetic Corrosion Analysis.
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PseudoScientist © 2002, 2007, 2009
The following episode is a true description of magnetic reactors built and test results obtained from using these reactors within the authors's test areas.
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Magnetic Corrosion: Copper Surface Etching. Residual Test Fluid.
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"Pseudoscientist" Page 73. Magnetic Corrosion: August 2004
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Previous analysis of Type II magnetic generators revealed that corrosion type patterns had developed on copper plated surfaces placed within the magunit reaction zone. These tests were reproducible using the same experimental test conditions. Magnetic corrosion was the only reproducible test result that Johhn had obtained from many years of magnetic testing.
This test series was set up to reproduce magnetic corrosion growth using the Vivator reactor. The primary goal of this analysis was further investigation of “magnetic fluid” intermittently detected during previous magnetic corrosion testing. Changes in corrosion characteristics due to reaction zone spacing and internal coil configuration would be evaluated.
Johhn built the Vivator magnetic reactor with the bulk flux generator placed on the bottom. The test plate was a dielectric plate with copper deposited on both surfaces, and this plate was placed directly onto the field pole surface of the bulk generator. The top magunit generator was placed directly onto the test plate, and radiation fields were established within the two generators. No external power or signal energy was input to the magunit assembly. The test plate was removed from the reaction zone after three days of magnetic activation.
As Johhn removed the test plate, he felt a wetness or fluid on the surface edges of the copper layer. He held the plate up for light surface analysis, but no thin film diffraction fringes were detected. When he touched the copper edge region again, he felt no wetness or any type of fluid sensation upon the test plate. The detected fluid may have evaporated into or reacted with the air ambient. Further inspection revealed no markings or discoloration patterns on the plate surface where the fluid was observed.
Sharply defined corrosion type patterns had developed on the top copper surface of the test plate. These patterns, which resembled cutting patterns with a sharp knife, had an average width of 0.06 inch. The sharp definition of these patterns did not correspond with the diffuse patterns usually caused by chemical corrosion.
Three more test plates produced sharply defined corrosion patterns, with identical pattern structure, using the same test conditions. The corrosion patterns were contained within a spiral structure on the copper plate surface, and this spiral type structure was reproduced on each test plate. There were no corrosion marks or patterns on the bottom plate surface.
The sharply defined corrosion patterns slowly degraded into diffuse surface patterns after one week of air storage and storage within plastic bag enclosures. The pattern width enlarged from 0.06 to 0.12 inch, and the bottom surface of the patterns had an “orange peel” pattern. There was no further pattern degradation over time.
Variations in magnetic corrosion patterns were analyzed when the air spacing between the top plate copper surface and magunit reactor surface was varied. When the spacing distance increased up to 0.5 inch, the depth of corrosion pattern decreased, but the pattern maintained sharp definition. Spacing distance greater than 0.5 inch produced no corrosion pattern or any feeling of fluid wetness on the test plate.
Johhn then placed a sheet of 24 lb. white paper between the surface of the test plate and the top magunit reactor. Test runs with activation times between three and ten days produced no corrosion patterns on the test plate surfaces. Subsequent test runs with 20 mil plastic sheet and waxed paper generated no corrosion marks or patterns on the test plate surface.
Further tests were carried out to determine the effect of increasing test activation time within the interfacial region. Reaction times less than five days produced sharp corrosion patterns within the copper surface with an average width of 0.06 inch. Activation times greater than five days produced broad diffuse corrosion patterns with an average width of 0.12 inch.
Tiny droplets of some fluid were still evident on the inside walls of the test plate bags after two weeks of test plate storage. Attempts to isolate these droplets by with Q-tips or filter paper were futile, since the droplets disappeared upon contact with air atmosphere.
A test plate made with two strips of photographic paper glued back to back, light exposed but not chemically developed, was placed between the bulk reactor and top magunit reactor. No markings were observed on either side of this photographic paper plate using a three day activation time. Both surfaces of the photographic test plate had uneven surfaces similar to absorption of water vapor within the photographic paper.
Further analysis of this photographic paper plate, after eight weeks storage of air storage, revealed five irregular corrosion spots, with diameters ranging from 0.25-0.50 inch, on the top side of the test strip. There was no further degradation of the photographic paper plate surfaces, stored in air ambient, after this observation date.
A single sheet of #150 grade aluminum oxide sandpaper was then placed within the reaction zone with the grain surface in the top position. There were no corrosion patterns or other markings on either side of this test plate upon removal from reaction zone seven days later. Inspection one week later showed no markings on the sandpaper sheet. Red circular growth patterns, with diameters from 0.1 inch to 0.25 inch, were observed within the grain surface of the sheet after immersion in filtered water for eight days.
The color of these aluminum oxide microorganisms was identical with the color of the motile red microorganisms detected during the Aquarium experiment last year. Tiny samples from these growth areas were used to seed nutrient agar and other growth medium petri dishes, but no microorganism growth patterns developed within the test cultures.
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