The increasing of popularity of implant treatments and the increasing number performed methods in recent time opens the new possibilities to use together the decontamination and adhesion of implant surface to the organic tissue. These studies are stimulated by a lot of incidence of short-term and long-term complications which took place in the last time. It is proposed a set of modern effects in the bimolecular interaction of radiation with the human organism in order to apply it in bioinformatics and modern medicine. Taking into consideration the advance equipment in photonics like photonic crystals and photonic-crystal fibre we are interested to use this optical systems in modern implants in order to treat the surface infection formed on the surface between the implant and cellular tissue in the process of poor adhesion. Considering the advanced equipments of modern photonics such as photonic crystals or photonic crystal fibers, we propose to use these optical systems in the controlling and managing of modern therapeutic implants. Such metamaterials like photonic crystals, each can be deposited on the implant surface and can be used as a dispersion of UV radiation on the large surface to treat infection on the surface between the implant and adhesion tissue. The adherence of implant to the human tissue may be accompanied to the growth of cells between the elements of bubble structure of implant surface. Here we have a possibility to restore periphery neuronal system in order to feel and to control the surface of the implant by the brain through our neuronal network.
It is proposed a quantum system formed from two coupled cavities, doped with radiators in two-level approximations. The coupling between cavities is realized by a semitransparent common mirror. The common mirror is subjected to induced classical vibrations. It is demonstrated that the vibrations influence the quantum entanglement between the atoms placed in different optical cavities. The exact solution of the Schrodinger equation was obtained. The influence of classical vibration of the mirror on the transfer of energy from one cavity to another was analyzed. The possibility to control the quantum correlation between atoms opens a new perspective of utilization of optical cavities for quantum information processing.
It is proposed a new approach in the estimation of quantum fluctuations of the electromagnetic field and Doppler effect using a model formed from two quantum modes of the cavity which propagate in opposite direction. The Doppler effect plays a significant role in the model in which an atom flies through the nodes and anti-nodes of the standing wave. It is shown that if the vacuum Rabi frequency achieves the value of Doppler shift kv, where k is the wave vector and v represents the atomic velocity, then the collective interactive and non-interactive modes of the resonator become connected. The interaction process looks like in the case of two coupled cavities in one of which is placed an atom. The comparison between the proposed approach and existing time dependent coupling model is given. In our model, it is obtained the non-zero value of quantum fluctuations in the nodes of the standing wave during the time in which atom flies through the cavity.
The resonance fluorescence of an atomic (or ion) system implanted in the materials driving two standing waves of the optical cavity is studied taking into consideration the delocalization of the atom. It is demonstrated that the resonance fluorescence depends on the position of atoms (or ions) relative the nodes or antinodes of standing waves. This situation gives us the possibility to measure the amplitude of mechanical oscillations of these radiators implanted in organic or inorganic materials. It is proposed to measure the amplitude of the mechanical oscillations relative to the equilibrium position using the time changes in the positions of the five peaks of the resonance fluorescence spectrum. In this case, the small oscillation amplitude relative to the standing wave length can drastically change the spectrum of resonance fluorescence of such atoms. The proposed method can be used in the measurements of the nanostructure temperature (or bio-molecule temperature deformation).
Taking into consideration the granulate glass deposition of the TiO2 glass we propose a phenomenological model describing the nonlinear process of the growth of Ti and TiO2 films on Si or SiO2 substrates as function of temperature. It is proposed that the phase transition can take place in earth granule so that the fixed Tg temperature is absent in comparison with traditional phase transition from thermodynamics. The continue temperature transition from crystalline to vitreous phase in the deposited films is analyzed based upon the nonlinear theory of phase transitions and the granulate aspect of deposited material.
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