Emergence of Dynamical Dissipative Structures in a Bistable Spin Crossover Solid Under Light: Experience and Theory

Abstract In this article, the basic spatiotemporal theory elucidating the physical conditions leading to the emergence of dissipative structures and pattern formation in spin‐crossover solids under light causing their photo‐heating is outlined. In this context, the spatiotemporal properties of the spin‐crossover (SC) transition are described as a reaction diffusion process. The time evolution of the spin state (the high spin fraction) is coupled to the spatiotemporal properties of temperature inside the lattice, accounting for: (i) the crystal photo‐heating, (ii) the coupling to thermal bath, and (iii) the thermal diffusion. It is demonstrated that around well‐defined unstable regions, this system leads to the emergence of nonstationary Turing patterns, dynamic dissipative structures, and autocatalytic oscillations of which an experimental example is provided on the SC single crystal ([{Fe(NCSe)(py) 2 } 2 ( m ‐bpypz)]). These results pave the way to a new fertilized field in the quest of nonlinear dynamics and morphogenesis in molecular switchable solids undergoing first‐order phase transitions.