Abstract
A key goal in molecular electronics has been to find molecules that facilitate efficient charge transport over long distances. Normally, molecular wires become less conductive with increasing length. Here, we report a series of fused porphyrin oligomers for which the conductance increases substantially with length by >10-fold at a bias of 0.7 V. This exceptional behavior can be attributed to the rapid decrease of the HOMO-LUMO gap with the length of fused porphyrins. In contrast, for butadiyne-linked porphyrin oligomers with moderate inter-ring coupling, a normal conductance decrease with length is found for all bias voltages explored (±1 V), although the attenuation factor (β) decreases from ca. 2 nm-1 at low bias to <1 nm-1 at 0.9 V, highlighting that β is not an intrinsic molecular property. Further theoretical analysis using density functional theory underlines the role of intersite coupling and indicates that this large increase in conductance with length at increasing voltages can be generalized to other molecular oligomers.
Highlights
Investigating length dependence and long-range charge transport across individual molecules is an important area of study related to many chemical and physical processes
Linked porphyrin tapes show remarkable electronic properties, and dramatic reductions in HOMO−LUMO gap with length, with some of the smallest gaps reported for organic compounds.[26]
We measured the low-bias conductance of each compound at a certain applied bias voltage (0.2 V for P1−3 and 0.1 V for fP2/3) using a home-built scanning tunneling microscope (STM), employing the break junction technique
Summary
Investigating length dependence and long-range charge transport across individual molecules is an important area of study related to many chemical and physical processes. Some junctions display traces with a ‘V’-shaped profile, whereas others have pronounced flat regions, but with a dip around zero-bias As this is clearly a voltage-related effect, and as the traces no longer fit with the shape expected in the off-resonant transport regime, we deduce that the molecule becomes temporarily charged due to the proximity of molecular levels to the Fermi level of (at least one of) the electrodes. The strong change in HOMO/LUMO energy along the fused series causes the effective barrier for electrons to change significantly as the length increases This logically implies that there is no single degree of attenuation per unit length for the fused porphyrins. This consideration highlights that β (as commonly defined21) is an approximation when applied to molecular oligomers, useful only when the effective barrier remains practically constant with length
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