Deformable Molecular Crystal on 2D Crystal: A New Way to Build Nanoscale Periodic Trapping Sites for Interlayer Excitons

TL;DR

This paper introduces a novel method using deformable 2D molecular crystals to create nanoscale periodic trapping sites for interlayer excitons, enabling new possibilities for exciton manipulation and quantum phases.

Contribution

It demonstrates how lattice deformation in organic/2D material heterostructures can generate periodic potential landscapes for excitons, a new approach compared to traditional moiré pattern methods.

Findings

PTCDI lattice distortion lifts molecular degeneracy

Periodic energy variation of ~0.2 eV with ~2 nm periodicity

Effective trapping of interlayer excitons at PTCDI/MoS2 interfaces

Abstract

The nanoscale moir\'e pattern formed at 2D transition metal dichalcogenide crystal (TMDC) heterostructures provides periodic trapping sites for excitons, which is essential for realizing various exotic phases such as artificial exciton lattices, Bose-Einstein condensates, and exciton insulators. At organic molecule/TMDC heterostructures, similar periodic potentials can be formed via other degrees of freedom. We utilize the structure deformability of a 2D molecular crystal as a degree of freedom to create a periodic nanoscale potential that can trap interlayer excitons (IXs). Specifically, two semiconducting molecules, PTCDI and PTCDA, which possess similar bandgaps and ionization potentials but form different lattice structures on MoS2, are investigated.The PTCDI lattice on MoS2 is distorted geometrically, which lifts the degeneracy of the two molecules within the crystal's unit cell. The degeneracy lifting results in a spatial variation of the molecular orbital energy, with an amplitude and periodicity of ~ 0.2 eV and ~ 2 nm, respectively. On the other hand, no such energy variation is observed in PTCDA/MoS2, where the PTCDA lattice is much less distorted. The periodic variation in molecular orbital energies provides effective trapping sites for IXs. For IXs formed at PTCDI/MoS2, rapid spatial localization of the electron in the organic layer towards the interface is observed, which demonstrate the effectiveness of these interfacial IX's traps.