As a primary energy source, electricity drives broad fields from everyday electronic circuits to
industrial chemical catalysis. From a chemistry viewpoint, studying electric field effects on …

Although it was demonstrated that discrete molecular levels determine the sign and
magnitude of the thermoelectric effect in single-molecule junctions, full electrostatic control …

We report quantum interference effects in the electrical conductance of chemical vapor
deposited graphene nanoconstrictions fabricated using feedback controlled electroburning …

We report a robust approach to fabricate single-molecule transistors with covalent electrode–
molecule–electrode chemical bonds, ultrashort (∼ 1 nm) molecular channels, and high …

Controllable single‐molecule logic operations will enable development of reliable ultra‐
minimalistic circuit elements for high‐density computing but require stable currents from …

Graphene provides a two-dimensional platform for contacting individual molecules, which
enables transport spectroscopy of molecular orbital, spin, and vibrational states. Here we …

Graphene electrodes are promising candidates to improve reproducibility and stability in
molecular electronics through new electrode–molecule anchoring strategies. Here we report …

This paper proposes a new dynamic behavior model for single-electron transistors (SETs). A
comprehensive review of modeling techniques and previous models was carried out aiming …

The recent synthesis of various hybrid porphyrin-graphene systems provides an attractive
platform to investigate exotic transport phenomena related to graphene-based spintronic …

We have reported the precise methodology for fabricating graphene quantum dots through
electroburning and performed measurements on the Coulomb blockade and oscillation …