BibTex format
@article{Fang:2026,
author = {Fang, F and Li, A and Geoghegan, B and Webb, T and Dang, Y and Bennett, T and Fu, K and Azaden, A and Vanin, F and Sills, A and Long, N and Haque, S and Roessler, M},
journal = {Nature Chemistry},
title = {Electron hopping in conjugated molecular wires with application to solar cells},
year = {2026}
}
RIS format (EndNote, RefMan)
TY - JOUR
AB - Electron transfer through molecular wires underpins numerous research fields, ranging from single molecule electronics to fundamental biological processes and their application in (bio)electrocatalysis. Here, we report a series of 1–3 nm long ferrocene terminated conjugated molecular wires, anchored to indium tin oxide electrodes, that exhibit an electron transfer mechanism dominated by hopping (with a β value of 0.043 Ź). We show that the nature of the electrode, namely the small energy gap between the electron donor and acceptor, explains the unexpected electron transfer mechanism in these short wires. We demonstrate the applicability of these anchored molecular wires in a tin perovskite solar cell as hole-extraction layer. We show improved performance in devices employing the molecular wire as compared to more conventional hole-extraction layers typically used in tin perovskite solar cells. This work not only opens avenues for mechanistic investigations of interfacial electron transfer using molecular wires, but also showcases their potential impact in applications e.g. in a solar cell.
AU - Fang,F
AU - Li,A
AU - Geoghegan,B
AU - Webb,T
AU - Dang,Y
AU - Bennett,T
AU - Fu,K
AU - Azaden,A
AU - Vanin,F
AU - Sills,A
AU - Long,N
AU - Haque,S
AU - Roessler,M
PY - 2026///
SN - 1755-4330
TI - Electron hopping in conjugated molecular wires with application to solar cells
T2 - Nature Chemistry
ER -