Non Equilibrium Thermodynamics for the Interactions of the See Quantum Scalar’s System with the Classical Bio Fields in the Cellular Cryobiology and Anhydrobiology

Institute for Cryobiology and Food Technologies, BG - 1407 Sofia, Bulgaria


TSVETKOV, Ts. D., G. PETROV and P. TSVETKOVA, 2006. Non equilibrium thermodynamics for the interactions of the see quantum scalar’s system with the classical bio fields in the cellular cryobiology and anhydrobiology. Bulg. J. Agric. Sci., 12: 621-628

The feature of the contemporary theoretical biological physics in the cryobiology (the study of the structure of living cells and systems at very low temperatures) and anhydrobiology (the study of the structure of living cells and systems at low water contents) is in common. The question above the possibility to find the complicate appearances connected with the existence of the life and the living systems his place in the mathematical frame of any one concrete quantum field theory by the contemporary state of the interactions of the virtual quantum field with the classical bio fields is open by the consideration of high topographical complementarities by the London-force interactions involved importantly in the highly specific and strong but purely physical complexing of enzymes with substrates, of antigens with antibodies, etc. From the new results by the contributions of the environmental freezing-drying and vacuum sublimation (Zwetkow, 1985; Tsvetkov et al., 1989, 2006; Belaus and Tsvetkov, 1985) is hopped that by the grate form expressed e.g. by the thermodynamically and kinetic jump behaviour of the living cells and systems will be possibly to describe the biological expressions by means of concrete quantum field system too. From a grate interest is the so called problem of the connection between the entropy and the time arrow. With other words the connection between the entropy and the causality according to quantum field theory of the interactions between a quantum field system and external classical bio field modelled by the additional boundary conditions e.g. by the Casimir effect.
It is knowing that one of the major causes of damage produced by the several effects at cellular level: (i) low temperature per se, (ii) direct effects of freezing and (iii) indirect effects of freezing and (iv) the biochemical modifications in the structure of the living cells by the lipids, phospholipids, proteins in the cell membrane formed by interacting of the “matter” fields such as a new electron distribution or the protonisation at a given time for the living cells and systems is freezing induced dehydration at very short distance scales, where various properties of the physical vacuum of any one concrete quantum field system, e.g. the systems of see scalars, for which the vacuum state must be conformed by means of the interactions with the classical bio fields or of additional boundary conditions are of crucial importance.
At the molecular level (Mitter and Robaschik, 1999) the thermodynamic behaviour is considered by any concrete quantum field system with additional boundaries as by the Casimir effect between the two parallel, perfectly conducting square plates (side L, distance d, L > d), embedded in a large cube (side L) with one of the plates at face an periodic boundary condition. It is considered contributions from the volume L2d between the plates resp. L2(L-d) outside have different temperature (outside T’, inside T). For the temperatures T’ < T, the external pressure is reduced in comparison with the standard situation (T’ = T). Therefore it is expected the existence of a certain distance d0, at which the Casimir attraction is compensated by the net radiation pressure. That is possibly to investigate this field equilibrium point for this system or for hydrological equilibrium of the system membrane-solutions-water and its stability both for an isothermal and an adiabatic treatment of the interior region.

Key words: impulse wave equation, van der Waals forces, Casimir effect, vitrification, living cells and systems and bio fields