Article, 2024

Direct Writing of Room Temperature Polariton Condensate Lattice

Nano Letters, ISSN 1530-6984, 1530-6992, Volume 24, 16, Pages 4945-4950, 10.1021/acs.nanolett.4c00586

Contributors

Yadav, Ravindra Kumar (Corresponding author) [1] Satapathy, Sitakanta 0000-0002-0318-3661 [1] Deshmukh, Prathmesh 0000-0003-4430-4068 [1] [2] Datta, Biswajit 0000-0002-7649-9667 [1] Sharma, Addhyaya [1] Olsson, Andrew H [3] Chen, Junsheng 0000-0002-2934-8030 [4] Laursen, Bo Wegge 0000-0002-1120-3191 [4] Flood, Amar H 0000-0002-2764-9155 [3] Sfeir, Matthew Y 0000-0001-5619-5722 [5] Menon, Vinod M (Corresponding author) [1] [2]

Affiliations

  1. [1] City College of New York
    2. [NORA names: United States; America, North; OECD];
  2. [2] The Graduate Center, CUNY
    3. [NORA names: United States; America, North; OECD];
  3. [3] Indiana University Bloomington
    4. [NORA names: United States; America, North; OECD];
  4. [4] University of Copenhagen
    5. [NORA names: KU University of Copenhagen; University; Denmark; Europe, EU; Nordic; OECD];
  5. [5] CUNY Advanced Science Research Center
    6. [NORA names: United States; America, North; OECD]

Abstract

Realizing lattices of exciton polariton condensates has been of much interest owing to the potential of such systems to realize analogue Hamiltonian simulators and physical computing architectures. Here, we report the realization of a room temperature polariton condensate lattice using a direct-write approach. Polariton condensation is achieved in a microcavity embedded with host-guest Frenkel excitons of an organic dye (rhodamine) in a small-molecule ionic isolation lattice (SMILES). The microcavity is patterned using focused ion beam etching to realize arbitrary lattice geometries, including defect sites on demand. The band structure of the lattice and the emergence of condensation are imaged using momentum-resolved spectroscopy. The introduction of defect sites is shown to lower the condensation threshold and result in the formation of a defect band in the condensation spectrum. The present approach allows us to study periodic, quasiperiodic, and disordered polariton condensate lattices at room temperature using a direct-write approach.

Keywords

Frenkel excitons, Hamiltonian simulation, analogues, approach, arbitrary lattice geometry, architecture, band, band structure, beam etching, computing architecture, condensate lattice, condensate spectrum, condensation, condensation threshold, defect band, defect sites, defects, direct-write approach, dye, emergency, etching, exciton-polariton condensates, excitons, focused ion beam etching, formation, geometry, introduction, introduction of defect sites, ion beam etching, lattice, lattice geometry, microcavity, momentum-resolved spectroscopy, organic dyes, polariton condensate, potential, realization, rhodamine, room, room temperature, simulation, sites, small-molecule ionic isolation lattices, smile, spectra, spectroscopy, structure, system, temperature, threshold, writing

Funders

  • United States Air Force Office of Scientific Research
  • Directorate for Mathematical & Physical Sciences
  • United States Army Research Office
  • Division of Materials Research
  • Office of Basic Energy Sciences

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