Understanding and tuning charge transport over a single molecule is a fundamental topic in
molecular electronics. Single-molecule junctions composed of individual molecules …

The concept of using single molecules as functional building blocks in electronic circuitry
represents the ultimate device miniaturization and has garnered tremendous attention from …

Integrating multidisciplinary efforts from physics, chemistry, biology, and materials science,
the field of single-molecule electronics has witnessed remarkable progress over the past two …

Control of conductance through a single molecule via alternating anchoring points provides
a unique perspective to design single-molecule electronic devices. A high conductance …

The ability to modulate and control charge transport though singlemolecule junction devices
is crucial to achieving the ultimate goal of molecular electronics: constructing real-world …

Over the past two decades, various techniques for fabricating nano-gapped electrodes have
emerged, promoting rapid development in the field of single-molecule electronics, on both …

We modulate the conductance of electrochemically inactive molecules in single-molecule
junctions using an electrolytic gate to controllably tune the energy level alignment of the …

Single molecule electronic devices in which individual molecules are utilized as active
electronic components constitute a promising approach for the ultimate miniaturization and …

Conspectus Quantum interference effects (QIEs), which offer unique opportunities for the
fine-tuning of charge transport through molecular building blocks by constructive or …

Controlling charge transport through molecules is challenging because it requires
engineering of the energy of molecular orbitals involved in the transport process. While side …