It was investigated how react molecular clusters in water, starch, bio-matrices, polymers and in quartz on gravitation radiation from planets. Gravitation radiation (GR) was found to influence the proton jumping in hydrogen bonds that stabilize the cluster structure. There was given a method calculating parameters of GR as well as a mechanism of its resonance interaction with weak GR from molecular matter (WGR). WGR has been defined as the result of proton dissolving in vacuum connected with its simultaneous condensation in the nearest free space. Both dissolving and condensation proceed with super light velocity. The gravitation wave length has been determined experimentally and it depends on the planet masses (between Earth and Sun λ ≥ 62 km, between Earth and Milky Way center λ ≥ 330 km). GR has been characterized with super light velocity. After analyzing the Sun influence on water two forms of protons were found: in a condensed and dissolved state. A new model for the atomic nucleus has been suggested according to which the protons in the nucleus oscillate between condensed and dissolved state, where in the case of isotopes this state is partially destroyed. The models for H2 and Be shall be given. Electron orbitals in atoms and molecules were found to be caused by a stationary front of shock waves from condensing protons
The long-range order in n-hexane, gasoline, diesel and in their mixtures with/without water is investigated by the gravitational mass spectroscopy (GMS). Molecular clusters are analyzed to be present in fuels and mixtures. Using GMS subtraction spectra for water in hydrocarbons, it becomes clear what role water plays and how it interact with the surroundings. Water in fuels is concluded to appear as individual clusters, whose structure (density) depends on the nature of hydrocarbon clusters. The combustion mechanism of hydrocarbons saturated with water will be discussed. Water clusters are suggested to accelerate the diffusion processes of the combustion. Molecular clusters in liquid fuels are formed in stationary gravitational waves of white noises, penetrating the Earth.
For collagen obtained from young fish air bubbles, using the gravitation mass spectroscopy method (GMS) the dynamics of the long-range order (LRO) change in the whole domain ensemble up to 3 billion Da was studied. LRO was represented by the masses of the simplest domains (loops, spirals), sub micelle and micelle structures, seed fibrillary crystals and giant aggregates (2...3 billion Da). The process of the LRO varying occurred under the influence of the gravitational noise (GN) from the universe. The form of the mass distribution in LRO depended on the age of the fish.
Figure 1:GMS spectra dry collagen from air bubble of young (A) and of two years old roach (B). The sub ensembles of mass concentrations (atom nuclei clusters) in collagen A were nominated as 1S ... 4S, aged as S1 ... S8. For some signals, the labeling 1, 3, 11, 20, 127 were given, this was the RASC number (repeating average structures in collagen) consisting of: Gly 22 -Pro % 13% -Hyp 10 % -Glu 9.8 % -Ala 8 % -Arg 7.6 % (mass %).
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