Dr. Erik P Hoy Ph.D.

Electronic devices constructed from single molecules can display unique transport behaviors derived from their inherently quantum-mechanical nature…

SESSION: COMP POSTER SESSION:  

Electronic devices constructed from single molecules make an excellent test platform for investigating how molecular effects such as structural changes and electron correlation can control charge transport at the single-molecule level…

Single-molecule electronic devices have long been a topic of intense study due to their unique charge transport characteristics. For example, in the traditional electronic resistor, conductance decays as the device length increases…

Tautomeric equilibria play an essential role in a wide array of natural chemical and biochemical reactions. Despite having structures that only differ by the position of one hydrogen atom, the chemical/biological properties of tautomers can vary considerably…

Molecular electronics have been a topic of intense study due to their unique charge transport characteristics which can be controlled at the quantum level…

Despite its potential importance for describing non-classical conductance and current behaviors, consistently capturing both dynamic and multireference electron correlation effects in nanoscale transport problems remains a major challenge for quantum mechanics-based charge transport methodologies…

Despite its potential importance for describing non-classical conductance and current behaviors, consistently capturing both dynamic and multireference electron correlation effects in nanoscale transport problems remains a major challenge for quantum mechanics-based charge transport methodologies…

: [COMP] Division of Computers in Chemistry

Despite its potential importance for describing non-classical conductance and current behaviors, consistently capturing both dynamic and multireference electron correlation effects in nanoscale transport problems remains a major challenge for quantum mechanics-based charge transport methodologies…

: [COMP] Division of Computers in Chemistry

Despite its potential importance for describing non-classical conductance and current behaviors, consistently capturing both dynamic and multireference electron correlation effects in nanoscale transport problems remains a major challenge for quantum mechanics-based charge transport methodologies…

Conductance decay reversals and ave received increasing attention due to recent experiments on topological insulators showing that it is possible to construct the systems . This potentially enables the creation of highly conducting molecular wires for a wide variety of applications…

Describing charge transport in nanoscale molecular electronics and sensors can be challenging due to the uniquely quantum character of these systems. This quantum character leads to intrinsic quantum phenomena not observed in traditional electronics and sensors…

Molecular junctions have been widely studied due to their potential to yield new classes of molecule-based electronic devices and sensors. These junctions often display unique transport characteristics compared to classical electronics…

Quantum Information Science (QIS) combines elements of physics, computer science, and information theory to study how quantum systems can be used to perform certain tasks that are considered challenging and/or sometimes impossible for many classical systems/sensors…

Single molecule electronic devices offer a promising alternative to traditional silicon-based electronics but remain challenging to model accurately in the presence of strong electron correlation effects…