Abstracts of reports presented in the IX International Scientific Conference "Matter, Energy, Gravitation", 7-11 Aug 2006, St. Petersburg, Russia

Program from the conference website  www.antidogma.ru/programma.zip

Unzipped program from this website programma.doc (2.3 MB)

Basic Structures of Matter - Supergravitation unified theory (BSM-SG) based on an alternative concept of the physical vacuum (plenary report)

Stoyan Sarg (Sargoytchev)

The Basic Structures of Matter - Super Gravitation Unified Theory (BSM-SG) unveils the relation between the forces in Nature by adopting the following framework:

- Empty Euclidian space without any physical properties and restrictions

- Two fundamental particles of superdense matter with parameters associated with the Planck’s scale

- A Fundamental law of Super Gravitation (SG) - an inverse cubic law valid in pure empty space.

An enormous abundance of these two particles, with vibrational energy beyond some critical level, are able to congregate into self-organized hierarchical levels of geometrical formations, based on the funda­mental SG law. A self-organized process leads deterministically to cre­ation of space with quantum properties (known as physical vacuum) and a galaxy as observable matter. All known laws of Physics are embedded in the underlying structure of the physical vacuum and the structure of the elementary particles. The fundamental SG law is behind the gravitational, electric and magnetic fields and governs all kinds of interactions between the elementary particles in the space of physical vacuum.



Major predictions of the BSM-SG unified theory:  space energy of non-EM type; super-communication by longitudinal waves; possibility to control the gravitational mass of material object (plenary report)

Stoyan Sarg (Sargoytchev)

The BSM-SG unified theory is based on a model of two fundamental superdense particles associated with the Planck’s scale and a Supergravitational law with inverse cubic dependence on distance in pure empty space. The new approach leads to understanding the underlying material structure of the physical vacuum, called a Cosmic Lattice  (CL) and the material structure of the elementary particles. The analysis of the CL node dynamics, the light propagation and the oscillation properties of the electron permits derivation of the basic CL space parameters and understanding the physical relation between the gravitational, electrical and magnetic fields. This put a light on the quantum and space-time properties of the physical vacuum and permits envisioning of unknown so far physical mechanisms. Among the major predictions of BSM-SG theory are: existence of space energy of non-EM type as a primary source of the nuclear energy; a possibility for supercommunication by non-EM waves and a possibility to control the gravitational mass of material object based on a particular physical mechanism.

SLIDES: Sarg_BSM-predictions.pdf


Material structure of the stable elementary particles and the atomic nuclei according to the BSM-SG unified theory (poster report)

Stoyan Sarg (Sargoytchev)

Among the major results of the BSM-SG unified theory based on a new concept of the physical vacuum is the unveiled material structure of the elementary particles and  the atomic nuclei. They are graphically presented in the appendix Atlas of Atomic Nuclear Structures covering the elements from Hydrogen to Uranium. The spatial arrangement of the protons and neutrons matches exactly the raw and column properties of the Periodic table of Mendeleev, while exhibiting features defining the chemical valence, Hund’s rule and Pauli Exclusion Principle. The finite size nuclear structure and the limited angular freedom of the valence protons with their valence electrons agree well with the VCEPR model used in chemistry. The unveiled atomic models are verified by the known structures of some organic molecules and biomolecules. The synthetic atomic models are potentially useful in the fields of nanotechnology, structural chemistry and biomolecules.

Pictures of the conference abstract booklet: title pages;   pages 80-81pages 82-83