Quantum Interference in Real-Time Electron-Dynamics: Gaining Insights from Time-Dependent Configuration Interaction Simulations

Quantum Interference ◽

Quantum Coherence ◽

Gold Atom ◽

Electron Injection ◽

Time Dependent ◽

Electron Dynamics ◽

Initial State ◽

Donor States

Femtosecond electron dynamics based on time-dependent configuration interaction (TDCI) is a numerically rigorous approach for quantitative modeling of electron-injection across molecular junctions. Our simulations of cyanobenzene thiolates---para- and meta-linked to an acceptor gold atom---corroborate aromatic resonance stabilization effects and show donor states \emph{conjugating} with the benzene $\pi$-network to exhibit superior electron-injection dynamics across the para-linked isomer compared to the meta counterpart. For a \emph{non-conjugating} initial state, we find electron-injection through the meta-channel to stem from non-resonant quantum mechanical tunneling. Furthermore, we demonstrate quantum interference to drive para- vs. meta- selectivity in the coherent evolution of superposed $\pi$(CN)- and $\sigma$(NC-C)-type wavepackets. Analyses reveal that in the para-linked molecule, $\sigma$, and $\pi$ MOs localized at the donor terminal are \emph{in-phase} leading to constructive interference of electron density distribution while phase-flip of one of the MOs in the meta-linked molecule results in destructive interference. The findings reported here suggest that \emph{a priori} detection of orbital phase-flip and quantum coherence conditions can aid in molecular device design strategies.

Quantum Interference in Real-Time Electron-Dynamics: Gaining Insights from Time-Dependent Configuration Interaction Simulations

10.26434/chemrxiv.11086292.v1 ◽

2019 ◽

Author(s):

Raghunathan Ramakrishnan

Keyword(s):

Quantum Interference ◽

Quantum Coherence ◽

Gold Atom ◽

Electron Injection ◽

Time Dependent ◽

Electron Dynamics ◽

Initial State ◽

Donor States

p.p1 {margin: 0.0px 0.0px 0.0px 0.0px; font: 11.0px Menlo; color: #000000; background-color: #ffffc9} span.s1 {font-variant-ligatures: no-common-ligatures} span.s2 {font-variant-ligatures: no-common-ligatures; color: #2cb11b} span.s3 {font-variant-ligatures: no-common-ligatures; color: #c611c6} span.s4 {font-variant-ligatures: no-common-ligatures; color: #be631a} Femtosecond electron dynamics based on time-dependent configuration interaction (TDCI) is a numerically rigorous approach for quantitative modeling of electron-injection across molecular junctions. Our simulations of cyanobenzene thiolates---para- and meta-linked to an acceptor gold atom---corroborate aromatic resonance stabilization effects and show donor states \emph{conjugating} with the benzene $\pi$-network to exhibit superior electron-injection dynamics across the para-linked isomer compared to the meta counterpart. For a \emph{non-conjugating} initial state, we find electron-injection through the meta-channel to stem from non-resonant quantum mechanical tunneling. Furthermore, we demonstrate quantum interference to drive para- vs. meta- selectivity in the coherent evolution of superposed $\pi$(CN)- and $\sigma$(NC-C)-type wavepackets. Analyses reveal that in the para-linked molecule, $\sigma$, and $\pi$ MOs localized at the donor terminal are \emph{in-phase} leading to constructive interference of electron density distribution while phase-flip of one of the MOs in the meta-linked molecule results in destructive interference. The findings reported here suggest that \emph{a priori} detection of orbital phase-flip and quantum coherence conditions can aid in molecular device design strategies.

Charge-Transfer Selectivity and Quantum Interference in Real-Time Electron Dynamics: Gaining Insights from Time-Dependent Configuration Interaction Simulations

10.26434/chemrxiv.11086292.v3 ◽

2020 ◽

Author(s):

Raghunathan Ramakrishnan

Keyword(s):

Electron Transfer ◽

Quantum Interference ◽

Quantum Coherence ◽

Gold Atom ◽

Electron Injection ◽

Time Dependent ◽

Donor States ◽

Meta Isomer

Many-electron wavepacket dynamics based on time-dependent configuration interaction (TDCI) is a numerically rigorous approach to quantitatively model electron-transfer across molecular junctions. TDCI simulations of cyanobenzene thiolates---para- and meta-linked to an acceptor gold atom---show donor states conjugating with the benzene $\pi$-network to allow better through-molecule electron migration in the para isomer compared to the meta counterpart. For dynamics involving non-conjugating states, we find electron-injection to stem exclusively from distance-dependent non-resonant quantum mechanical tunneling, in which case the meta isomer exhibits better dynamics. Computed trend in donor-to-acceptor net-electron transfer through differently linked azulene bridges agrees with the trend seen in low-bias conductivity measurements. Disruption of $\pi$-conjugation has been shown to be the cause of diminished electron-injection through the 1,3-azulene, a pathological case for graph-based diagnosis of destructive quantum interference. Furthermore, we demonstrate quantum interference of many-electron wavefunctions to drive para- vs. meta- selectivity in the coherent evolution of superposed $\pi$(CN)- and $\sigma$(NC-C)-type wavepackets. Analyses reveal that in the para-linked benzene, $\sigma$ and $\pi$ MOs localized at the donor terminal are in-phase leading to constructive interference of electron density distribution while phase-flip of one of the MOs in the meta isomer results in destructive interference. These findings suggest that a priori detection of orbital phase-flip and quantum coherence conditions can aid in molecular device design strategies.

Charge-Transfer Selectivity and Quantum Interference in Real-Time Electron Dynamics: Gaining Insights from Time-Dependent Configuration Interaction Simulations

10.26434/chemrxiv.11086292 ◽

2020 ◽

Author(s):

Raghunathan Ramakrishnan

Keyword(s):

Electron Transfer ◽

Quantum Interference ◽

Quantum Coherence ◽

Gold Atom ◽

Electron Injection ◽

Time Dependent ◽

Donor States ◽

Meta Isomer

Many-electron wavepacket dynamics based on time-dependent configuration interaction (TDCI) is a numerically rigorous approach to quantitatively model electron-transfer across molecular junctions. TDCI simulations of cyanobenzene thiolates---para- and meta-linked to an acceptor gold atom---show donor states conjugating with the benzene $\pi$-network to allow better through-molecule electron migration in the para isomer compared to the meta counterpart. For dynamics involving non-conjugating states, we find electron-injection to stem exclusively from distance-dependent non-resonant quantum mechanical tunneling, in which case the meta isomer exhibits better dynamics. Computed trend in donor-to-acceptor net-electron transfer through differently linked azulene bridges agrees with the trend seen in low-bias conductivity measurements. Disruption of $\pi$-conjugation has been shown to be the cause of diminished electron-injection through the 1,3-azulene, a pathological case for graph-based diagnosis of destructive quantum interference. Furthermore, we demonstrate quantum interference of many-electron wavefunctions to drive para- vs. meta- selectivity in the coherent evolution of superposed $\pi$(CN)- and $\sigma$(NC-C)-type wavepackets. Analyses reveal that in the para-linked benzene, $\sigma$ and $\pi$ MOs localized at the donor terminal are in-phase leading to constructive interference of electron density distribution while phase-flip of one of the MOs in the meta isomer results in destructive interference. These findings suggest that a priori detection of orbital phase-flip and quantum coherence conditions can aid in molecular device design strategies.