Molecules with high Seebeck coefficients (S) have potential applications in thermoelectric materials. However, their S values at single-molecule and self-assembled monolayer levels are low partly due to large energy gaps (E–E_F) between molecular frontier orbital energy and Fermi energy of the electrodes. We have recently reported highly conducting organometallic molecules with electron-rich ruthenium tetraphosphine fragments in molecular junction. The theoretical study suggests that their small energy gaps (E–E_F), which may lead to a large Seebeck coefficient. In this study, we report the Seebeck coefficient of multinuclear ruthenium complexes bridged by p-diethynylbenzene-diyl linkers and examine their thermoelectric properties.
Thermoelectric measurements for mono-, di- and tri-ruthenium complexes were conducted using the Au-molecule-EGaIn/Ga₂O₃ system. Upon heating the gold electrode, the S values increased with the number of metal fragments, and the trinuclear complex showed a value exceeding 70 µV/K, which is the highest S value obtained by SAM junction reported so far. Theoretical calculations and cyclic voltammograms indicate that the high Seebeck coefficient is caused by the high-lying HOMO, which destabilizes as the number of metal fragments increases.