Interpenetrating frameworks are described as architectures which cannot be separated except if one of the individual motifs is broken. 1 In their complicated architectures, supramolecular connections (such as electrostatic interaction, hydrogen bond, πÀπ stacking, and cationÀπ interactions) among the individual motifs endow them with structural flexibility, which is important in the applications of gas storage, conductivity, biological chemistry, and so on. 2 Interpenetration is a subclass of entangled system studied extensively and developed rapidly nowadays. Individual motifs of the interpenetrating architectures are from two-dimensional (2D) nets to three-dimensional (3D) frameworks, and the number of interpenetrating units varies from 2 to 10. 3 Ongoing research in interpenetration focuses on the introduction of functional groups with available characters.Polyoxometalates (POMs) are early transition metal oxide clusters composed of Mo, W, V, Nb, and so on. POMs show a wide variety of interesting structural motifs with different sizes and topologies. Besides the classical Keggin, WellsÀDawson, Anderson, Waugh, Silverton, and Lindqvist types, many new structures have been found, such as closed cages, Wheels, dimeric anions, and transition-metal-centered heteropolyoxometalates. 4 POMs are in the nanosize scale and have abundant surface oxygen atoms, which make them excellent inorganic building blocks. In addition, POMs bear versatile properties in such fields as catalysis, photochemistry, magnetism, electrochemistry, and biochemistry. 5,6 Accordingly, POM-based interpenetrating compounds will not only show aesthetic architectures but also possess both properties of flexibility of interpenetration and versatile functions of POMs. 7 However, to obtain such compounds is difficult as the nanosized POMs with a big steric hindrance would inhibit the formation of interpenetration.Ag þ ion is a prominent metal linker in the POM-based metal organic frameworks (MOFs), for it not only possesses abundant coordination modes such as linear, T-type, "seesaw", "squarepyramidal", "trigonal-bipyramidal" and octahedral geometries 8 but also is useful in the areas of catalysis, biological chemistry, and so on. 9 In addition, the argentophilicity of Ag þ ions may conduce the formation of {Ag 2 } 2þ dimers, which may play a key role in the expansion of multiple dimensional structures. {Ag 2 } 2þ dimers acting as linkers can be classified into unsupported and supported ones according to their coordination modes; that is, two Ag þ ions in an unsupported {Ag 2 } 2þ dimer are fused only by Ag I 3 3 3 Ag I interaction, while those in a supported {Ag 2 } 2þ dimer are connected not only by Ag I 3 3 3 Ag I interaction but also by