Electron Acceleration and Quantized Velocity

This paper analyzes and discusses electron motion between electron spots in adjacent spot cubes based on a physical interpretation of binary mechanical (BM) space [1] [2]. Quantization of electron velocity is predicted. Fig. 1 shows the X1 level of the YZ surface of two adjacent spot cubes (left and right) as might be seen from above the YZ plane of the page.

Fig. 1: X1 Plane of YZ Surface of Two Adjacent Spot Cubes
Legend: Each color-coded spot is a 2x2x2 cube of bits. A spot cube contains 8 spots, 4 of which are partially visible in this view. Electron spots (e-L; yellow) and right (R) and left (L) d quark (d) spots (r, red; w, white; b, blue). Mites (circles) and lites (arrows and stars) may be in the 0-state (white) or 1-state (black). Stars are lites moving toward the viewer. Purple arrows indicate the direction of the three inter-dimensional strong bit operations within a spot, one of which is visible in each spot in this view.

Gravity Looses Primary Force Status

Binary mechanics (BM) [1] depreciates gravity from a primary force with the working hypothesis that observed gravity effects are the result of the four fundamental bit operations -- unconditional, scalar, vector and strong. This article presents observations supporting this hypothesis.

It was found that acceleration of two bodies toward each other depended on a higher bit density between the two bodies than in other directions around the bodies. Further, attraction of two bodies conventionally described as gravity required a minimum bit density in the space between the bodies.

Discussion of these results suggests that space-time curvature, such as postulated in the General Theory of Relativity by Einstein is not required to explain gravity or other related observations, and indeed, probably does not even exist in the absence of data requiring it.