Abstract and Introduction
As a consequence of binary mechanics (BM) fundamentals [1], a motion law states that objects tend to move in the direction of higher vacuum energy density [2]. As background, topics discussed include particles as compositions of multiple quanta, the mechanism of particle movement as a flux of individual quanta [3], the most likely motion direction and the equivalence of the gravitational field within a solid object and a quanta density gradient in its perfect vacuum component [4]. Predictions from this model have been confirmed by experimental results of Alex L Dmitriev et al, reporting weight decease with a (1) heated brass rod, (2) heating a piezo ceramic pile, (3) laser injection in optical fibers and (4) in gyros proportional to spin frequency and with horizontal more than vertical spin axis. The role of temperature in gravity-like effects has now been studied in two broad categories: distant objects not in direct contact and the special case of a weighed object resting on a scale.
Fig. 1: Motion Law At Single Particle Level
Abstract and Introduction
A gravitational wave [1] observed at LIGO (Laser Interferometer Gravitational-Wave Observatory) [2] may provide experimental confirmation of two major results of binary mechanics (BM) [3]: (1) objects tend to move toward regions of higher vacuum energy density [4] [5] [6] and (2) light speed in vacuum decreases at reduced vacuum energy density [7] [8]. This paper outlines how the BM model of gravitational effects and the land-mark light speed discovery may fully account for the LIGO gravitational wave data.
Table 1: LIGO Gravitational Wave Mechanism and Detection
Gravity has been viewed as a primary force by physicists for over a century. As the theory of binary mechanics (BM) [1] developed, the author assumed that gravitation would take its place among the primary forces which generally corresponded to four discrete bit operations -- unconditional, electromagnetic (scalar and vector) and strong, determining the time-development of a physical system. Hence, the initial assumption was that gravity would have its own bit operation to bring the total to five operators on BM states. However, simulation experiments produced gravity-like effects without postulation of any additional gravity-related bit operation, a result that strongly suggested that gravity was not a primary force at all.
Gravitation looses primary force status
In these experiments [2], the initial state consisted of two bodies (volumes with higher 1-state bit densities than surrounding space). Then the four postulated BM bit operations were applied repeatedly, while observing changes in the system. Acceleration of the two bodies toward each other was found and appeared to depend on a higher bit density between the two bodies than in other directions around the bodies. This conclusion was readily observed. Each body radiated 1-state bits to its lower density surroundings. Obviously, the space between the objects would develop a higher 1-state bit density than any other direction.
Abstract presented at April 13-16 APS meeting:
Bulletin of the American Physical Society 58(4) 186 (2013)
Abstract and Introduction
Quantitatively large effects of lunar surface temperature on apparent gravitational force measured by lunar laser ranging (LLR) and lunar perigee may challenge widely accepted theories of gravity. LLR data [1] grouped by days from full moon shows the moon is about 5 percent closer to earth at full moon compared to 8 days before or after full moon. In a second, related result, moon perigees were least distant in days closer to full moon. Moon phase was used as proxy independent variable for lunar surface temperature. These results support the prediction by binary mechanics (BM) [2] that gravitational force increases with object surface temperature [3].
Methods and Results
Fig. 1: Lunar Distance vs Days from Full Moon
