The Space Structure, Force Fields, and Dark Matter

Ding-Yu Chung; Volodymyr Krasnoholovets

doi:10.4236/jmp.2013.44A005

Journal of Modern Physics > Vol.4 No.4A, April 2013

The Space Structure, Force Fields, and Dark Matter

Ding-Yu Chung, Volodymyr Krasnoholovets
Institute of Physics, National Academy of Sciences, Kyiv, Ukraine.
Utica, Michigan, USA.
DOI: 10.4236/jmp.2013.44A005 PDF HTML 3,717 Downloads 6,006 Views Citations

Abstract

It is proposed that the digital space structure consists of attachment space (denoted as 1) for rest mass and detachment space (denoted as 0) for kinetic energy. Attachment space attaches to object permanently with zero speed, and detachment space detaches from the object at the speed of light. The combination of attachment space and detachment space brings about the three structures: binary lattice space, miscible space, and binary partition space. Binary lattice space, (1 0)_n, consists of repetitive units of alternative attachment space and detachment space. In miscible space, attachment space is miscible to detachment space without separation. Binary partition space, (1)_n(0)_n, consists of separated continuous phases of attachment space and detachment space. Binary lattice space, miscible space, and binary partition space constitute quantum mechanics, special relativity, and the extreme force fields, respectively. Through the detachment space, a higher dimensional particle in attachment space is sliced into infinitely surrounding a lower dimensional core attachment space, resulting in a particle surrounding by gauge field in the form of binary lattice space. The 10d particle can be sliced into 9d, 8d, 7d, 6d, 5d, and 4d particles equally by mass, corresponding to baryonic particle as 4d and dark matter as other 5 particles, so the ratio between baryonic matter and dark matter is 1 to 5, in agreement with the observed ratio. At extreme conditions, such as extremely low temperature, the gauge force field in the form of binary lattice space is transformed into the extreme force field in the form of binary partition space to explain extreme phenomena, such as superconductivity.

Keywords

Space Structure; Quantum Mechanics; Force Fields; Dark Matter; Superconductivity

Share and Cite:

D. Chung and V. Krasnoholovets, "The Space Structure, Force Fields, and Dark Matter," Journal of Modern Physics, Vol. 4 No. 4A, 2013, pp. 27-31. doi: 10.4236/jmp.2013.44A005.

Conflicts of Interest

The authors declare no conflicts of interest.

References

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