Enhanced Thermopower of Saturated Molecules by Noncovalent Anchor‐Induced Electron Doping of Single‐Layer Graphene Electrode

Abstract Enhancing thermopower is a key goal in organic and molecular thermoelectrics. Herein, it is shown that introducing noncovalent contact with a single‐layer graphene (SLG) electrode improves the thermopower of saturated molecules as compared to the traditional gold–thiolate covalent contact. Thermoelectric junction measurements with a liquid‐metal technique reveal that the value of Seebeck coefficient in large‐area junctions based on n ‐alkylamine self‐assembled monolayers (SAMs) on SLG is increased up to fivefold compared to the analogous junction based on n ‐alkanethiolate SAMs on gold. Experiments with Raman spectroscopy and field‐effect transistor analysis indicate that such enhancements benefit from the creation of new in‐gap states and electron doping through noncovalent interaction between the amine anchor and the SLG electrode, which leads to a reduced energy offset between the Fermi level and the transport channel. This work demonstrates that control of interfacial bonding nature in molecular junctions improves the Seebeck effect in saturated molecules.