Atomically precise single-crystal structures of electrically conducting 2D metal-organic frameworks.
Jin-Hu DouMaxx Q ArguillaYi LuoJian LiWeizhe ZhangLei SunJenna L MancusoLuming YangTianyang ChenLucas R ParentGrigorii SkorupskiiNicole J LiBrettoChenyue SunMin Chieh YangPhat Vinh DipEdward J BrignoleJeffrey T MillerJing KongChristopher H HendonJunliang SunMircea DincǎPublished in: Nature materials (2020)
Electrically conducting 2D metal-organic frameworks (MOFs) have attracted considerable interest, as their hexagonal 2D lattices mimic graphite and other 2D van der Waals stacked materials. However, understanding their intrinsic properties remains a challenge because their crystals are too small or of too poor quality for crystal structure determination. Here, we report atomically precise structures of a family of 2D π-conjugated MOFs derived from large single crystals of sizes up to 200 μm, allowing atomic-resolution analysis by a battery of high-resolution diffraction techniques. A designed ligand core rebalances the in-plane and out-of-plane interactions that define anisotropic crystal growth. We report two crystal structure types exhibiting analogous 2D honeycomb-like sheets but distinct packing modes and pore contents. Single-crystal electrical transport measurements distinctively demonstrate anisotropic transport normal and parallel to the π-conjugated sheets, revealing a clear correlation between absolute conductivity and the nature of the metal cation and 2D sheet packing motif.