The new fundamental physical theory, quantum–classical mechanics (QCM), takes into account the chaotic dynamics of the transient state (TS) in electron-phonon transitions [1–3]. In the case of strong transient (dozy) chaos QCM gives the same result as the standard Franck–Condon picture of electronic-vibrational transitions [4]. Dozy chaos (DC) provides the convergence of a series of time-dependent perturbation theory which is absent in the standard quantum picture [2]. In the case of weak DC, an important result of QCM is the Egorov nano-resonance (Enr), which is associated with the appearance of a pronounced regular dynamics against the background of DC and which explains the nature of the narrow and intense optical J-band of the well-known J-aggregates [5]. The discovery of QCM and Enr opens up the possibility of creating optical spectroscopy of extended molecular systems, in which, along with DC, the effects of regular dynamics in TS are significant. DC in TS is provoked by a light electron “in order” to ensure the reorganization of a very heavy nuclear subsystem, and hence the very possibility of electronic-vibrational transitions. This organizing property of the electron undoubtedly plays an enormous role in biological processes. The next stage in the development of QCM can be to complicate the system by organizing various aggregates, where the “elementary cell” in the theory and/or the starting point for the development of the theory will be the already solved problem of elementary electron transfers in QCM [6]. The purpose of such complication and enumeration of all possible variants of aggregation will be to find the “molecule of life”, that is, the rather complex, but “minimal” structural configurations, in which elements of self-organization, both structural and dynamic, observed in theoretical optical spectra, are clearly manifested. The “atom of life” here is the electron itself which provokes DC. Thus, through the increasing complexity of the design of molecular systems, QCM opens up great prospects for the search and study of the simplest forms of life organization and related phenomena. For example, a new kind of possible materials, “living materials”, can provide us with much more comfortable living conditions [6]. Advanced artificial living beings (ALBs), created based on targeted molecular systems design and engineering, and, for example, radiation-resistant, will be able to greatly help humanity in future space exploration [6]. On planet Earth, diverse communities of ALBs will represent a virtually unlimited source of skilled labor in all areas of human activity and entirely under human control. Among other things, ALBs will give impetus to the creation of the most effective form of socio–economic and moral organization of human civilization (see [6] and references therein), which is unattainable under the currently existing egoistic paradigm of human society [7], which arose as a result of a long evolutionary process.