Emergent Above-Gap Photoluminescence in Molecularly Engineered Hybrid Bilayer Crystals

Emergent Above-Gap Photoluminescence in Molecularly Engineered Hybrid Bilayer Crystals

Bilayer crystals, built by stacking two-dimensional (2D) covalent monolayers, give rise to coupled excitonic states whose properties are constrained by fixed lattice symmetry and orientation. Replacing one covalent monolayer with a 2D molecular crystalheld together by noncovalent forcesovercomes t...

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Auteur principal: Tomojit Chowdhury (6285287) (author)
Autres auteurs: Aurélie Champagne (15213726) (author), Patrick Knüppel (22676009) (author), Zehra Naqvi (20934322) (author), Ariana Ray (7651370) (author), Mengyu Gao (5545958) (author), David A. Muller (1568509) (author), Nathan P. Guisinger (1383159) (author), Kin Fai Mak (1901236) (author), Jeffrey B. Neaton (1262847) (author), Jiwoong Park (1661347) (author)
Publié: 2025
Sujets:
Biophysics
Cell Biology
Biotechnology
Ecology
Computational Biology
Astronomical and Space Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
Physical Sciences not elsewhere classified
strong polarization anisotropy
perfectly linear power
peak 120 mev
directly growing single
based bilayer platform
atomically thin optoelectronic
ab initio </
plane lattice geometry
fixed lattice symmetry
delocalized excitonic states
fully quenches pl
demonstrating molecular control
7 </ sup
2 </ sub
gap emission 
excitonic emission
lattice scale
gap emission
excitonic phenomena
∼ 10
work introduces
stacking two
robust photoluminescence
report four
quantum materials
ptcda monolayer
powerful knob
law dependence
intermolecular spacing
interlayer coupling
give rise
gap photoluminescence
exciton engineering
excitation density
excellent agreement
coexisting localized
calculations reveal
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Description
Résumé:Bilayer crystals, built by stacking two-dimensional (2D) covalent monolayers, give rise to coupled excitonic states whose properties are constrained by fixed lattice symmetry and orientation. Replacing one covalent monolayer with a 2D molecular crystalheld together by noncovalent forcesovercomes this limitation, as molecular functional groups afford tunable in-plane lattice geometry, intermolecular spacing, and interlayer coupling, providing a powerful knob for exciton engineering. Here, we report four-atom-thick hybrid bilayer crystals (HBCs) synthesized by directly growing single-crystalline PDI molecular crystal atop WS<sub>2</sub> monolayers, which exhibit a robust photoluminescence (PL) peak 120 meV above the WS<sub>2</sub> optical band gap alongside a below-gap emission. Both peaks display strong polarization anisotropynearing unity for the above-gap emissionand maintain a perfectly linear power-law dependence up to an excitation density of ∼10<sup>7</sup> mW/cm<sup>2</sup>, indicative of coexisting localized and delocalized excitonic states. Substituting PDI with a PTCDA monolayer on WS<sub>2</sub> fully quenches PL, demonstrating molecular control over excitonic emission. Lattice scale <i>ab initio</i> GW and Bethe–Salpeter equation (BSE) calculations reveal a significantly hybridized bilayer band structure in PDI/WS<sub>2</sub> that supports interlayer excitonic species both above and below the WS<sub>2</sub> gap with strong polarization anisotropy, in excellent agreement with experiment. Our work introduces a molecule-based bilayer platform for the bottom-up design and control of excitonic phenomena in atomically thin optoelectronic and quantum materials.

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