Singular and Nonsingular Transitions in the Infrared Plasmons of Nearly Touching Nanocube Dimers.
Yina WuAndrea KonečnáShin Hum ChoDelia J MillironJordan A HachtelF Javier García de AbajoPublished in: ACS nano (2024)
Narrow gaps between plasmon-supporting materials can confine infrared electromagnetic energy at the nanoscale, thus enabling applications in areas such as optical sensing. However, in nanoparticle dimers, the nature of the transition between touching (zero gap) and nearly nontouching (nonzero gap ≲15 nm) regimes is still a subject of debate. Here, we observe both singular and nonsingular transitions in infrared plasmons confined to dimers of fluorine-doped indium oxide nanocubes when moving from touching to nontouching configurations depending on the dimensionality of the contact region. Through spatially resolved electron energy-loss spectroscopy, we find a continuous spectral evolution of the lowest-order plasmon mode across the transition for finite touching areas, in excellent agreement with the simulations. This behavior challenges the widely accepted idea that a singular transition always emerges in the near-touching regime of plasmonic particle dimers. The apparent contradiction is resolved by theoretically examining different types of gap morphologies, revealing that the presence of a finite touching area renders the transition nonsingular, while one-dimensional and point-like contacts produce a singular behavior in which the lowest-order dipolar mode in the touching configuration, characterized by a net induced charge in each of the particles, becomes unphysical as soon as they are separated. Our results provide valuable insights into the nature of dimer plasmons in highly doped semiconductors.
Keyphrases
- quantum dots
- high resolution
- magnetic resonance imaging
- photodynamic therapy
- energy transfer
- molecular dynamics
- computed tomography
- magnetic resonance
- high glucose
- endothelial cells
- oxidative stress
- diabetic rats
- metal organic framework
- diffusion weighted imaging
- atomic force microscopy
- positron emission tomography
- pet imaging