The influence of dark excitons on the electroabsorption spectrum of polyacetylene

TL;DR

This paper investigates how dark excitons influence the electroabsorption spectrum of polyacetylene, revealing differences between cis and trans isomers and identifying the role of dark excitons in the spectral features.

Contribution

It demonstrates the activation of dark excitons in trans-polyacetylene and links their presence to spectral features and exciton ordering, providing new insights into exciton dynamics.

Findings

Dark excitons are activated in trans-polyacetylene under electric field.

The $1B_u$ exciton lifetime is estimated to be ~30 fs.

EA spectrum of trans-polyacetylene shows a Huang-Rhys series with S~0.5.

Abstract

This study revisits the electroabsorption (EA) spectrum of polyacetylene, as functions of the electric field strength, isomerization degree, and light polarization states. The EA spectrum of $cis$-$(CH)_x$ reveals an oscillatory feature that follows the Stark shift-related first derivative of the materials absorption spectrum that contains v(0-1) and v(0-2) sidebands of the excited $C=C$ stretching vibration that agrees well with the Raman spectrum. EA spectrum of $trans $-$(CH)_x$ does not match the first derivative of the materials absorption spectrum, and the phonon sideband frequency does not agree with the RS spectrum. EA spectrum of $trans $-$(CH)_x$ reveals a band below the first allowed $1B_u$ exciton. We interpret this feature as due to the electric field activated even-parity dark (forbidden) exciton, namely $mA_g$ ($m >1$), showing that the nonluminescent $trans $-$(CH)_x$ is due to the reverse order of the excited states, where a dark $mA_g$ exciton lies below the allowed $1B_u$ exciton. This agrees with the unusual phonon sideband in $trans $-$(CH)_x$ absorption, since the excited state attenuation caused by the fast internal conversion from $1B_u$ to $mA_g$ influences the apparent frequency that determines the phonon sideband. Consequently, from the EA and RS spectra we estimate the $1B_u$ lifetime in $trans $-$(CH)_x$ to be $\sim 30$ fs. Integrated EA spectrum of $trans $-$(CH)_x$ shows a traditional Huang-Rhys type series with a relaxation parameter, $S \sim 0.5$. This indicates that the EA spectrum of the $trans $ isomer is also determined by a Stark shift related to the first derivative of the absorption spectrum, but preferentially for the longest chains in the films chain lengths distribution. This is due to the $N^3$ response of the non-linear susceptibility, $\chi^{(3)}$ ($\sim$EA), dependence on the chain length having $N$ monomers.