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
Inertial Propulsion may be described as conversion of angular momentum to linear momentum thus violating Newton’s mechanics in which these momentum types are separately conserved [1]. For example, Eric Laithwaite [2] and others have demonstrated translation motion of a gyro only when spinning called “precession”, as well as apparent levitation. Unlike Newton’s mechanics, the time-development laws of binary mechanics (BM) [3] [4] do not specifically require separate conservation of angular and linear momentum. However, energy (1-state bits called quanta) is conserved in BM. In fact, the BM time-development laws produce quanta motion alternating routinely between circular motion and translation and are the mechanism of inertial propulsion.
Fig. 1: Circular and Translation Quanta Motion in Electron Cycle
Legend: 3 spot units in electron spot (yellow). Centers of M and L bit loci size L cubes (white circles/arrows respectively) are equidistant from, and orthogonal to, the spin axis (grey circle) which is a spot cube solid diagonal (orthogonal to the spin and page planes).
