Controlling optical properties and drag of photon and surface plasmon polaritons in triple quantum dot molecules and dots-metal plasmonic interface via tunneling-assisted quantum coherence

•Controlling optical properties and drag of photon and SPPs in quantum dots and dots-metallic interface via tunneling-assisted quantum coherence.•The role of dressed sates on the light propagation, optical properties and drag of photon and SPPs.•The maximum positive (negative) value of the group ind...

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Published in:Optics and laser technology 2022-05, Vol.149, p.107915, Article 107915
Main Authors: Bashir, Azmat Iqbal, Zahir, Asif, Khan, Naveed, Hayat, S. Sikander
Format: Article
Language:English
Subjects:
Coherence
Drag
Eigenvalues
Interdot electron tunneling
Lateral and rotary drag
Optical properties
Photons
Plasmonic interface
Plasmonics
Polaritons
Propagation
Quality factor
Quantum dots
Quantum phenomena
Superluminal propagation
Surface plasmon polaritons
Wave propagation
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Summary:•Controlling optical properties and drag of photon and SPPs in quantum dots and dots-metallic interface via tunneling-assisted quantum coherence.•The role of dressed sates on the light propagation, optical properties and drag of photon and SPPs.•The maximum positive (negative) value of the group index for photon and SPPs is 3.68×106 (2.685×106) and 3×105.•The maximum value of lateral drag for photon and SPPs is ±5×10-2 and ±1.173×10-3, respectively.•The calculated propagation length and wavelength for SPPs are 6.25×10-7 m 3.78×10-7 m which correspond to the quality factor of 10.38. Optical properties of surface plasmon polaritons (SPPs) and drag of photon and SPPs attracted great attention owing to multi-fold potential fundamental and technological implications. In this paper, we investigate the nature of light propagation, optical properties of probe field and SPPs and drag of photon and SPPs in a four-level triple quantum dot molecule (TQDM) well and a dots-metallic plasmonic interface (DMPI). The quantum coherence in TQDM and coupled DMPI interface is achieved via interbands tunneling-assisted quantum coherence namely- classical electromagnetically induced transparency (EIT) and plasmonic induced transparency (PIT). In contrast to earlier studies, herein we employed Drude-model type dielectric constant of metal with inclusion of size-dependent correction term to account for the reduced electron relaxation rate near the thin metal interface. In particular, after solving the master density-matrix equation of the quantum dot system for the eigenvalues, we interpreted the calculated theoretical results on light dragging and optical properties of probe field and SPPs via tunneling-assisted dressed-state picture of EIT/PIT in the proposed TQDM system and DMPI interface. The tunneling parameter considerably tuned the nature of light propagation from subluminal to superluminal and vice versa, optical properties and drag of photon and SPPs. The maximum positive (negative) value of the group index for photon is of order 3.68×106 (2.685×106) while for SPPs it is of order 3×105. The maximum value of lateral drag for photon and SPPs is ±5×10-2m and ±1.173×10-3m, respectively. The calculated propagation length and wavelength for SPPs are 6.25×10-7m and 3.78×10-7 m which correspond to the quality factor of 10.38.
ISSN:0030-3992
1879-2545
DOI:10.1016/j.optlastec.2022.107915