Charge Transport and Conductance Switching of Redox‐Active Azulene Derivatives |
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Authors: | Dr. Florian Schwarz Dr. Michael Koch Dr. Georg Kastlunger Prof. Heinz Berke Dr. Robert Stadler Dr. Koushik Venkatesan Dr. Emanuel Lörtscher |
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Affiliation: | 1. Science and Technology Department, IBM Research – Zürich, Rüschlikon, Switzerland;2. Chemie Departement, University of Zurich, Zürich, Switzerland;3. Institut für Theoretische Physik, TU Wien – Vienna University of Technology, Vienna, Austria |
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Abstract: | Azulene (Az) is a non‐alternating, aromatic hydrocarbon composed of a five‐membered, electron‐rich and a seven‐membered, electron‐poor ring; an electron distribution that provides intrinsic redox activity. By varying the attachment points of the two electrode‐bridging substituents to the Az center, the influence of the redox functionality on charge transport is evaluated. The conductance of the 1,3 Az derivative is at least one order of magnitude lower than those of the 2,6 Az and 4,7 Az derivatives, in agreement with density functional theory (DFT) calculations. In addition, only 1,3 Az exhibits pronounced nonlinear current–voltage characteristics with hysteresis, indicating a bias‐dependent conductance switching. DFT identifies the LUMO to be nearest to the Fermi energy of the electrodes, but to be an active transport channel only in the case of the 2,6 and the 4,7 Az derivatives, whereas the 1,3 Az derivative uses the HOMO at low and the LUMO+1 at high bias. In return, the localized, weakly coupled LUMO of 1,3 Az creates a slow electron‐hopping channel responsible for the voltage‐induced switching due to the occupation of a single molecular orbital (MO). |
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Keywords: | azulene charge transport hopping molecular switch redox-activity |
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