Strong Coupling between Self-Assembled Molecules and Surface Plasmon Polaritons.

We experimentally demonstrate strong coupling between self-assembled PTCDI-C7 organic molecules and the electromagnetic mode generated by surface plasmon polaritons (SPPs). The system consists of a dense self-assembly of ordered molecules evaporated directly on a thin gold film, which stack perpendicularly to the metal surface to form H-aggregates, without a host matrix. Experimental wavevector-resolved reflectance spectra show the formation of hybrid states that display a clear anticrossing, attesting the strong coupling regime with a Rabi splitting energy of ΩR ≃ 102 meV at room temperature. We demonstrate that the strength of the observed strong coupling regime derives from the high degree of organization of the dense layers of self-assembled molecules at the nanoscale that results in the concentration of the oscillator strength in a charge-transfer Frenkel exciton, with a dipole moment parallel to the direction of the maximum electric field. We compare our results to numerical simulations of a transfer matrix model and reach good qualitative agreement with the experimental findings. In our nanophotonic system, the use of self-assembled molecules opens interesting prospects in the context of strong coupling regimes with molecular systems.

[1]  W. Barnes,et al.  Strong coupling between surface plasmon polaritons and emitters , 2018 .

[2]  Y. Zhao,et al.  Orientation-Dependent Exciton-Plasmon Coupling in Embedded Organic/Metal Nanowire Heterostructures. , 2017, ACS nano.

[3]  Nicholas J. Hestand,et al.  Molecular Aggregate Photophysics beyond the Kasha Model: Novel Design Principles for Organic Materials. , 2017, Accounts of chemical research.

[4]  J. Toppari,et al.  Dynamics of Strongly Coupled Modes between Surface Plasmon Polaritons and Photoactive Molecules: The Effect of the Stokes Shift , 2017 .

[5]  Sandeep Kumar,et al.  Liquid crystals in photovoltaics: a new generation of organic photovoltaics , 2017 .

[6]  L. Douillard,et al.  Fluorescent Self-Assembled Molecular Monolayer on Graphene , 2016 .

[7]  Daniele Sanvitto,et al.  The road towards polaritonic devices. , 2016, Nature materials.

[8]  Dongho Kim,et al.  Direct observation of ultrafast coherent exciton dynamics in helical π-stacks of self-assembled perylene bisimides , 2015, Nature Communications.

[9]  T. Ebbesen,et al.  Ultra-strong coupling of molecular materials: spectroscopy and dynamics. , 2015, Faraday discussions.

[10]  W. Barnes,et al.  Strong coupling between surface plasmon polaritons and emitters: a review , 2014, Reports on progress in physics. Physical Society.

[11]  Carlos Silva,et al.  H- and J-aggregate behavior in polymeric semiconductors. , 2014, Annual review of physical chemistry.

[12]  U. Hohenester,et al.  Absence of mutual polariton scattering for strongly coupled surface plasmon polaritons and dye molecules with a large Stokes shift , 2013 .

[13]  Keliang He,et al.  Orientation of luminescent excitons in layered nanomaterials. , 2013, Nature nanotechnology.

[14]  J. R. Krenn,et al.  Surface plasmon leakage radiation microscopy at the diffraction limit. , 2011, Optics express.

[15]  S. Latil,et al.  Janus-like 3D tectons: self-assembled 2D arrays of functional units at a defined distance from the substrate. , 2011, Angewandte Chemie.

[16]  T. Ebbesen,et al.  Reversible switching of ultrastrong light-molecule coupling , 2011, 2011 Conference on Lasers and Electro-Optics Europe and 12th European Quantum Electronics Conference (CLEO EUROPE/EQEC).

[17]  B. Sanders,et al.  Superradiance, subradiance, and suppressed superradiance of dipoles near a metal interface , 2010, 1007.5259.

[18]  F. Spano The spectral signatures of Frenkel polarons in H- and J-aggregates. , 2010, Accounts of chemical research.

[19]  T. Shahbazyan,et al.  Plasmon-mediated superradiance near metal nanostructures , 2010, 1001.0422.

[20]  M. Pettersson,et al.  Vacuum Rabi splitting and strong-coupling dynamics for surface-plasmon polaritons and rhodamine 6G molecules. , 2009, Physical review letters.

[21]  J. Plenet,et al.  Particularities of surface plasmon–exciton strong coupling with large Rabi splitting , 2008 .

[22]  Pablo G. Etchegoin,et al.  Erratum: “An analytic model for the optical properties of gold” [J. Chem. Phys. 125, 164705 (2006)] , 2007 .

[23]  V. Savona,et al.  Bose–Einstein condensation of exciton polaritons , 2006, Nature.

[24]  T. Jones,et al.  Photophysics of PTCDA and Me-PTCDI thin films: effects of growth temperature. , 2006, The journal of physical chemistry. B.

[25]  Romuald Houdré,et al.  Early stages of continuous wave experiments on cavity‐polaritons , 2005 .

[26]  T. Fritz,et al.  Formation of solid-state excitons in ultrathin crystalline films of PTCDA: from single molecules to molecular stacks. , 2004, Physical review letters.

[27]  J. Mugnier,et al.  Strong coupling between surface plasmons and excitons in an organic semiconductor. , 2004, Physical review letters.

[28]  J. Bloch,et al.  High-temperature ultrafast polariton parametric amplification in semiconductor microcavities , 2001, Nature.

[29]  Roel Baets,et al.  Optical modelling of photonic crystals and VCSELs using eigenmode expansion and perfectly matched layers , 2001 .

[30]  E. Sudhölter,et al.  Liquid Crystalline Perylene diimides : Architecture and Charge Carrier Mobilities , 2000 .

[31]  Jean-Michel Gérard,et al.  Strong-coupling regime for quantum boxes in pillar microcavities: Theory , 1999 .

[32]  A. Nurmikko,et al.  Stimulated emission, gain, and coherent oscillations in II-VI semiconductor microcavities , 1997 .

[33]  R. W. Christy,et al.  Optical Constants of the Noble Metals , 1972 .