Coordination assembly of 2D ordered organic metal chalcogenides with widely tunable electronic band gaps

Engineering the band gap chemically by organic molecules is a powerful tool with which to optimize the properties of inorganic 2D materials. The obtained materials are however still limited by inhomogeneous compositions and properties at nanoscale and small adjustable band gap ranges. To overcome these problems in the traditional exfoliation and then organic modification strategy, an organic modification and then exfoliation strategy was explored in this work for preparing 2D organic metal chalcogenides (OMCs). Unlike the reported organically modified 2D materials, the inorganic layers of OMCs are fully covered by long-range ordered organic functional groups. By changing the electron-donating ability of the organic functional groups and the electronegativity of the metals, the band gaps of OMCs were varied by 0.83 eV and their conductivities were modulated by 9 orders of magnitude, which are 2 and 10 7 times higher than the highest values observed in the reported chemical methods, respectively. Here, the authors report a new class of 2D materials with inorganic metal chalcogenide layers covered by long-range ordered organic groups. The range of modulation on their band gaps and electrical conductivities are two times and 7 orders of magnitude better than the highest values reported so far.