Mach Field Sensor / Detector and Results

Abstract

After recent (2017) meetings with scientists in the US and UK, the Mach field sensor/detector device has undergone refinements. Experiments run during test and control periods indicate that anomalous electromagnetic interactions with the device were reproducible by undergraduate research engineers at Bucknell University during the summer of 2018. These empirical investigations continue to yield results that are inexplicable by standard theory and are indicative of the potential that local Machian mass interactions are detectable (and potentially electromagnetic in nature) during significant alignments of relatively near masses (Earth, Moon, Sun, Virgo supercluster, etc.). This paper highlights the most recent results of experiments with the sensor/detector with additional 4 and 5 sigma events observed at Bucknell University this summer and captured in real-time by the system s new DAS (data acquisition system). The Newton-Mach paradigm, held by a minority of physicists, suggests that the underlying cause of inertia in matter is based on an action-at-a-distance interaction between that local matter and the remaining matter of the universe. These findings suggest a reaction Mach field (or force), electromagnetic in nature, is detectable when a high-inertia, rotating wheel is accelerated, decelerated, maintained at speed and/or is torqued. Our team herein reports a dozen (12) high magnitude (>40mV) outliers with high sigma (>4) without similar false positives in over a 100 recent experiments. We observe these significantly different electromagnetic forces around this high inertia device manifest in inexplicable voltage changes in the different batteries around the sensor array. Additionally, disturbances in the isotropy of space due to ‘local’ matter alignments appear to be causal in these electromagnetic anomalies. Alternative rational (and probable) explanators have yet to be identified to account for the regularity with which high-sigma outliers are observed on the device arms facing these large local mass alignments,.