Highly tunable room-temperature plexcitons in monolayer WSe2 /gap-plasmon nanocavities

The advancement of quantum photonic technologies relies on the ability to precisely control the degrees of freedom of optically active states. Here, we realize real-time, room-temperature tunable strong plasmon-exciton coupling in 2D semiconductor monolayers enabled by a general approach that combines strain engineering plus force- and voltage-adjustable plasmonic nanocavities. We show that the exciton energy and nanocavity plasmon resonance can be controllably toggled in concert by applying pressure with a plasmonic nanoprobe, allowing in operando control of detuning and coupling strength, with observed Rabi splittings>100 meV. Leveraging correlated force spectroscopy, nano-photoluminescence (nano-PL) and nano-Raman measurements, augmented with electromagnetic simulations, we identify distinct polariton bands and dark polariton states, and map their evolution as a function of nanogap and strain tuning. Uniquely, the system allows for manipulation of coupling strength over a range of cavity parameters without dramatically altering the detuning. Further, we establish that the tunable strong coupling is robust under multiple pressing cycles and repeated experiments over multiple nanobubbles. Finally, we show that the nanogap size can be directly modulated via an applied DC voltage between the substrate and plasmonic tip, highlighting the inherent nature of the concept as a plexcitonic nano-electro-mechanical system (NEMS). Our work demonstrates the potential to precisely control and tailor plexciton states localized in monolayer (1L) transition metal dichalcogenides (TMDs), paving the way for on-chip polariton-based nanophotonic applications spanning quantum information processing to photochemistry.

[1]  Ashley P. Saunders,et al.  Photoluminescence upconversion in monolayer WSe2 activated by plasmonic cavities through resonant excitation of dark excitons , 2023, Nature communications.

[2]  S. Cabrini,et al.  Near-Field Coupling with a Nanoimprinted Probe for Dark Exciton Nanoimaging in Monolayer WSe2 , 2023, Nano letters.

[3]  B. Hecht,et al.  Anticrossing of a plasmonic nanoresonator mode and a single quantum dot at room temperature , 2023, 2305.06909.

[4]  M. Raschke,et al.  Tip-Enhanced Dark Exciton Nanoimaging and Local Strain Control in Monolayer WSe2. , 2022, Nano letters.

[5]  Qianpeng Zhang,et al.  Strong Coupling in a Hybrid System of Silver Nanoparticles and J-Aggregates at Room Temperature , 2022, The Journal of Physical Chemistry C.

[6]  J. M. Marmolejo-Tejada,et al.  Theoretical quantum model of two-dimensional propagating plexcitons. , 2022, The Journal of chemical physics.

[7]  Vienna University of Technology,et al.  Strain control of hybridization between dark and localized excitons in a 2D semiconductor , 2022, Nature communications.

[8]  A. Truscott,et al.  Negative-mass exciton polaritons induced by dissipative light-matter coupling in an atomically thin semiconductor , 2022, Nature Communications.

[9]  N. Talebi,et al.  Tailoring the Band Structure of Plexcitonic Crystals by Strong Coupling , 2022, ACS Photonics.

[10]  B. Jonker,et al.  Nanoscale Optical Imaging of 2D Semiconductor Stacking Orders by Exciton‐Enhanced Second Harmonic Generation , 2021, Advanced Optical Materials.

[11]  C. Schneider,et al.  Tunable exciton-polaritons emerging from WS2 monolayer excitons in a photonic lattice at room temperature , 2021, Nature Communications.

[12]  B. Hecht,et al.  Single quantum emitter Dicke enhancement , 2020, 2010.12585.

[13]  A. Fieramosca,et al.  Ultralow Threshold Polariton Condensate in a Monolayer Semiconductor Microcavity at Room Temperature. , 2020, Nano letters.

[14]  J. Kysar,et al.  Facile and quantitative estimation of strain in nanobubbles with arbitrary symmetry in 2D semiconductors verified using hyperspectral nano-optical imaging. , 2020, The Journal of chemical physics.

[15]  J. Hone,et al.  Exciton dipole orientation of strain-induced quantum emitters in WSe2. , 2020, Nano letters.

[16]  M. S. Skolnick,et al.  Highly nonlinear trion-polaritons in a monolayer semiconductor , 2019, Nature Communications.

[17]  E. Pop,et al.  Dry Transfer of van der Waals Crystals to Noble-Metal Surfaces to Enable Characterization of Buried Interfaces. , 2019, ACS applied materials & interfaces.

[18]  Jeremy J. Baumberg,et al.  Extreme nanophotonics from ultrathin metallic gaps , 2019, Nature Materials.

[19]  M. Raschke,et al.  Tip-enhanced strong coupling spectroscopy, imaging, and control of a single quantum emitter , 2019, Science Advances.

[20]  M. Lorke,et al.  Quantum-Dot-Like States in Molybdenum Disulfide Nanostructures Due to the Interplay of Local Surface Wrinkling, Strain, and Dielectric Confinement. , 2019, Nano letters.

[21]  D. Norris,et al.  Room-Temperature Strong Coupling of CdSe Nanoplatelets and Plasmonic Hole Arrays , 2018, Nano letters.

[22]  R. Blaikie,et al.  Revealing Strong Plasmon-Exciton Coupling between Nanogap Resonators and Two-Dimensional Semiconductors at Ambient Conditions. , 2018, Physical review letters.

[23]  A. Pasupathy,et al.  Strain Engineering and Raman Spectroscopy of Monolayer Transition Metal Dichalcogenides , 2018, Chemistry of Materials.

[24]  H. Atwater,et al.  Nanoscale doping heterogeneity in few-layer WSe2 exfoliated onto noble metals revealed by correlated SPM and TERS imaging , 2018 .

[25]  B. Hecht,et al.  Near-field strong coupling of single quantum dots , 2018, Science Advances.

[26]  M. Rohlfing,et al.  Strain Control of Exciton-Phonon Coupling in Atomically Thin Semiconductors. , 2018, Nano letters.

[27]  D. Zahn,et al.  Highly Localized Strain in a MoS2/Au Heterostructure Revealed by Tip-Enhanced Raman Spectroscopy. , 2017, Nano letters.

[28]  M. Raschke,et al.  Radiative control of dark excitons at room temperature by nano-optical antenna-tip Purcell effect , 2017, Nature Nanotechnology.

[29]  J. Baumberg,et al.  Strong-coupling of WSe2 in ultra-compact plasmonic nanocavities at room temperature , 2017, Nature Communications.

[30]  T. Shegai,et al.  Observation of Mode Splitting in Photoluminescence of Individual Plasmonic Nanoparticles Strongly Coupled to Molecular Excitons. , 2017, Nano letters.

[31]  J. Hone,et al.  Nanobubble induced formation of quantum emitters in monolayer semiconductors , 2016, 1612.06416.

[32]  F. Guinea,et al.  Universal shape and pressure inside bubbles appearing in van der Waals heterostructures , 2016, Nature Communications.

[33]  Andrew R. Salmon,et al.  SERS of Individual Nanoparticles on a Mirror: Size Does Matter, but so Does Shape , 2016, The journal of physical chemistry letters.

[34]  J. Warner,et al.  Room-temperature exciton-polaritons with two-dimensional WS2 , 2016, Scientific Reports.

[35]  J. Aizpurua,et al.  Generalized circuit model for coupled plasmonic systems. , 2015, Optics express.

[36]  D. F. Ogletree,et al.  Revealing Optical Properties of Reduced-Dimensionality Materials at Relevant Length Scales , 2015 .

[37]  Sefaattin Tongay,et al.  Visualizing nanoscale excitonic relaxation properties of disordered edges and grain boundaries in monolayer molybdenum disulfide , 2015, Nature Communications.

[38]  Garnett W. Bryant,et al.  The Morphology of Narrow Gaps Modifies the Plasmonic Response , 2015 .

[39]  Fengnian Xia,et al.  Strong light–matter coupling in two-dimensional atomic crystals , 2014, Nature Photonics.

[40]  L. Novotný,et al.  Enhancement and quenching of single-molecule fluorescence. , 2006, Physical review letters.

[41]  M. Raschke,et al.  Supporting Information to: Hybrid Tip-Enhanced Nanospectroscopy and Nanoimaging of Monolayer WSe2 with Local Strain Control , 2016 .

[42]  T. P. Kaloni,et al.  Strain engineering of WS 2 , WSe 2 , and WTe 2 , 2014 .