Radicals are unique molecular systems for applications in electronic devices due to their
open-shell electronic structures. Radicals can function as good electrical conductors and …

Quantum interference (QI)—the constructive or destructive interference of conduction
pathways through molecular orbitals—plays a fundamental role in enhancing or …

This paper describes the thermoelectric properties of molecular junctions incorporating
multinuclear ruthenium alkynyl complexes that comprise Ru (dppe) 2 [dppe= 1, 2-bis …

Organic materials are promising candidates for thermoelectric cooling and energy
harvesting at room temperature. However, their electrical conductance (G) and Seebeck …

Quantum interference (QI) dominates the electronic properties of single molecules even at
room temperature and can lead to a large change in their electrical conductance. To take …

In this minireview, we discuss important aspects of the various quantum phenomena (such
as quantum interference, spin-dependent charge transport, and thermoelectric effects) …

Electron propagation through a molecular device is determined by its quantum electronic
structure. We employ molecular conductance orbitals (MCOs) to predict and interpret …

The discovery of air-stable organic radicals has sparked interest in their applications in
molecular electronics and spintronics. These radicals possess open-shell electronic …

The development of stimuli responsive systems that can switch between two distinct spin
states under the application of an external stimulus has always remained an elusive …

Single-molecule magnetic junctions provide versatile platforms for use in manipulating spin-
polarized currents via fine-tuning the electronic properties of the sandwiched molecule. We …