In recent years, porous coordination polymers (PCPs) or metal-organic frameworks (MOFs) with flexible structures have attracted considerable attention, owing to their potential as functional materials.[1] Unlike rigid frameworks, where, in most cases, structure and properties remain unchanged after removal of guest molecules, flexible frameworks are very sensitive to the presence of guests and undergo structural variations depending upon the amount and nature of the guest molecules inside the framework.[2] Such compounds are capable of forming bistable phases and are expected to exhibit not only structural variations but also modulation of their physical properties, such as chirality as well as optical and magnetic behavior, to achieve multiple functions that are not observed in robust frameworks or other conventional solids. Structural flexibility has also been observed in inorganic frameworks, although the detected changes are not as drastic as those of PCPs. To create such systems, we have focused on modulation of the crystal structure by reversible removal of guest molecules, to produce multifunctional bistable coordination polymers. If the host framework undergoes singlecrystal-to-single-crystal (SCSC) transformations, [3] crystallographic analysis is a very useful tool for deepening our understanding of the dynamic behavior, and correlating the bistable structures with physical properties, such as magnetism.[1d, 4] PCPs containing flexible ligands and metal ions with variable coordination numbers have great potential for this purpose, as such flexibility allows for stability in various structural forms.Porous crystals based on 2D frameworks have several useful characteristics with regard to dynamic guest-responsive phenomena: 1) interlayer separations, which play a major role in guest-inclusion; 2) framework flexibility, as a result of sliding of the 2D layers and closing/opening of the channel spaces by the guest molecules; 3) rearrangement of the frameworks by cleavage and formation of coordination bonds between the layers, leading to expansion/shrinkage of the 2D layered structures by the guest molecules. Most importantly, the transformation between the 2D and 3D frameworks, with cleavage and generation of new bonds, is expected to lead to large differences in their structural and functional behaviors. These unique materials have a high potential for realizing new functions, such as switching and sensing. To make bistable compounds with drastic structural differences, 2D frameworks containing a flexible ligand and a metal ion with variable coordination numbers may easily undergo transformation to a 3D structure upon guest removal by contracting/expanding and concurrent sliding of the 2D layers, using the bond-switching mechanism of the coordination bonds around the metal centers (Figure 1). [5][6][7][8] In this regard, the Cu II metal ion is very promising, as it has versatile coordination chemistry and can readily adopt octahedral, square-pyramidal, trigonal bipyramidal, and square-planar geometries. H...
