Theory of light-induced current in molecular-tunneling junctions excited with intense shaped pulses

TL;DR

This paper develops a theoretical framework for light-induced current in molecular-tunneling junctions under intense shaped optical pulses, proposing optical control methods to enhance charge transfer and exploring potential applications in opto-electronic devices.

Contribution

It introduces a new theoretical model for light-induced current in molecular junctions considering energy and electron transfer, and proposes a chirped pulse control method for charge transfer enhancement.

Findings

Analytical and numerical solutions for charge transfer dynamics.

Chirped pulses can enhance charge transfer in unbiased junctions.

Landau-Zener transition describes the control mechanism.

Abstract

A theory for light-induced current by strong optical pulses in molecular-tunneling junctions is described. We consider a molecular bridge represented by its highest occupied and lowest unoccupied levels, HOMO and LUMO, respectively. We take into account two types of couplings between the molecule and the metal leads: electron transfer that gives rise to net current in the biased junction and energy transfer between the molecule and electron-hole excitations in the leads. Using a Markovian approximation, we derive a closed system of equations for the expectation values of the relevant variables: populations and molecular polarization that are binary, and exciton populations that are tetradic in the annihilation and creation operators for electrons in the molecular states. We have proposed an optical control method using chirped pulses for enhancing charge transfer in unbiased junctions where the bridging molecule is characterized by a strong charge-transfer transition. An approximate analytical solution of the resulting dynamical equation is supported by a full numerical solution. When energy transfer between the molecule and electron-hole excitations in the leads is absent, the optical control problem for inducing charge transfer with linearly chirped pulse can be reduced to the Landau-Zener transition to a decaying level. When chirp is fast with respect to the rate of the electron transfer, the Landau theory is recovered. The proposed control mechanism is potentially useful for developing novel opto-electronic single-electron devices with optical gating based on molecular nanojunctions.