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Abstract The concept of a dozy chaos in the theory of quantum transitions and its applications are discussed in a historical context. Conjectured that dozy chaos is of primary importance to the dynamic self-organization of any living organism and concentrated in its brain. A hypothesis of the physical origin of cancer is put forward. Surmised that dozy chaos is the physical origin of life and driving force of its evolution.

It is well known that sometimes happen in science events that radically change our ideas about the world around us and have a tremendous impact on the subsequent development of both the science and the entire human civilization. The discovery of quanta in the beginning of last century [1] is without doubt a shining example of this kind of events. The discovery of quanta has not only revolutionized the whole of physics, but also formed the basis of modern chemistry, biology and the technologies associated with them. The recent theoretical discovery of a dozy chaos, that is a heart of the dynamic self-organization of the transient state in quantum transitions, can be in its significance on a par with such events. Dozy chaos was introduced into science at the beginning of the twenty first century as a novel physical substance to describe extended multiphonon transitions [2–5]. The necessity for introducing this substance stems from the presence of inherent singularity in the probability of extended transitions as a result of transit beyond the adiabatic approximation [6] in the quantum mechanics of electronnuclear motion. The fundamental role of the adiabatic approximation underlying the theories of molecular structure, solid state, and modern quantum chemistry is universally recognized. The motion of a light electron in the stationary state very quickly

V.V. Egorov () Russian Academy of Sciences, Photochemistry Center, 7a Novatorov Street, Moscow, Russia e-mail: [email protected] S.G. Stavrinides et al. (eds.), Chaos and Complex Systems, DOI 10.1007/978-3-642-33914-1 6, © Springer-Verlag Berlin Heidelberg 2013

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(adiabatically) adjusts itself to the slow motion of heavy nuclei. The stationary electron charge density distribution creates a potential in which nuclei vibrate about their equilibrium positions. However, the situation is altogether different with electron transitions from one stationary state to another, leading to a change in the electron charge density distribution and creation of a new potential in which nuclei vibrate about their new equilibrium positions. In other words, electron transitions cause equilibrium positions of the nuclei to shift; this process is frequently described as reorganization of nuclear vibrations. Bearing in mind the incommensurability of the electron and surrounding nuclei masses, the first question is how the light electron makes heavy nuclei leave their equilibrium positions for new ones. The correct answer to this question immediately poses another: How does the electron stop nuclei after they reach new equilibrium positions? The

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