posted on 2016-06-30, 00:00authored byTobias Neumann, Jianxi Liu, Tobias Wächter, Pascal Friederich, Franz Symalla, Alexander Welle, Veronica Mugnaini, Velimir Meded, Michael Zharnikov, Christof Wöll, Wolfgang Wenzel
In
the past, nanoporous metal–organic frameworks (MOFs)
have been mostly studied for their huge potential with regard to gas
storage and separation. More recently, the discovery that the electrical
conductivity of a widely studied, highly insulating MOF, HKUST-1,
improves dramatically when loaded with guest molecules has triggered
a huge interest in the charge carrier transport properties of MOFs.
The observed high conductivity, however, is difficult to reconcile
with conventional transport mechanisms: neither simple hopping nor
band transport models are consistent with the available experimental
data. Here, we combine theoretical results and new experimental data
to demonstrate that the observed conductivity can be explained by
an extended hopping transport model including virtual hops through
localized MOF states or molecular superexchange. Predictions of this
model agree well with precise conductivity measurements, where experimental
artifacts and the influence of defects are largely avoided by using
well-defined samples and the Hg-drop junction approach.