Nonlinear optical response of a two-dimensional quantum-dot supercrystal: Emerging multistability, periodic and aperiodic self-oscillations, chaos, and transient chaos

Abstract: We conduct a theoretical study of the nonlinear optical response of a two-dimensional semiconductor quantum dot supercrystal subjected to a quasi-resonant continuous wave excitation. A constituent quantum dot is modeled as a three-level ladder-like system (comprising the ground, the one-exciton, and the bi-exction states). To study the stationary response of the supercrystal, we propose an exact linear parametric method of solving the nonlinear steady-state problem, while to address the supercrystal optical dy… Show more

“…the ladder [14][15][16] and Λ schemes of optical transitions [17]. It should be noted in this connection that in spite of the global similarity of responses of the abovementioned systems of three-level QEs, the physics of the optical response formation of a V-QE monolayer differs significantly from the other two analogs.…”

“…The Rabi amplitude Ω(t) is the sum of the Rabi amplitudes Ω 0 = d 31 E 0 / of the external field and of the field produced by other V-QEs in place of the given V-QE. In the mean-field approximation, Ω(t) is given by the following equation [16] (here and in what follows, we suppress the time dependence of all variables):…”

“…(5) The expressions for constants γ R and Δ L depend on the relationship between the lateral lattice size Na (N is the lateral number of sites and a is the lattice constant) and radiation wavelength λ = 2πc/ω 0 , c being the speed of light. For a simple square lattice with lateral size Na ≪ λ (pointlike system), the quantities γ R and Δ L are given by [16] (6) (7) where = λ/2π. In the opposite case of Na ≫ λ (extended system), we have [16] (8) (9) As follows from Eqs.…”

“…For a simple square lattice with lateral size Na ≪ λ (pointlike system), the quantities γ R and Δ L are given by [16] (6) (7) where = λ/2π. In the opposite case of Na ≫ λ (extended system), we have [16] (8) (9) As follows from Eqs. (6) L a V-QEs in the lattice, while the value of γ R for an extended system is proportional to the number of V-QEs within an area of size .…”

“…However, nonlinear optical properties of 2D SCs have been investigated to a far lesser extent. It was shown in recent publications [14][15][16][17] that the nonlinear response of a SC of quantum emitters (QEs) with a ladder scheme [14][15][16] and Λ scheme of optical transitions [17] exhibits multistability, self-oscillations, and dynamic chaos. In addition, in a certain frequency range, the SC almost totally reflects the incident field, i.e., operates as an ideal nanometer-thick mirror, which, in addition, exhibits bistability.…”

Nonlinear Optical Dynamics and High Reflectance of a Monolayer of Three-Level Quantum Emitters with a Doublet in the Excited State

“…the ladder [14][15][16] and Λ schemes of optical transitions [17]. It should be noted in this connection that in spite of the global similarity of responses of the abovementioned systems of three-level QEs, the physics of the optical response formation of a V-QE monolayer differs significantly from the other two analogs.…”

“…The Rabi amplitude Ω(t) is the sum of the Rabi amplitudes Ω 0 = d 31 E 0 / of the external field and of the field produced by other V-QEs in place of the given V-QE. In the mean-field approximation, Ω(t) is given by the following equation [16] (here and in what follows, we suppress the time dependence of all variables):…”

“…(5) The expressions for constants γ R and Δ L depend on the relationship between the lateral lattice size Na (N is the lateral number of sites and a is the lattice constant) and radiation wavelength λ = 2πc/ω 0 , c being the speed of light. For a simple square lattice with lateral size Na ≪ λ (pointlike system), the quantities γ R and Δ L are given by [16] (6) (7) where = λ/2π. In the opposite case of Na ≫ λ (extended system), we have [16] (8) (9) As follows from Eqs.…”

“…For a simple square lattice with lateral size Na ≪ λ (pointlike system), the quantities γ R and Δ L are given by [16] (6) (7) where = λ/2π. In the opposite case of Na ≫ λ (extended system), we have [16] (8) (9) As follows from Eqs. (6) L a V-QEs in the lattice, while the value of γ R for an extended system is proportional to the number of V-QEs within an area of size .…”

“…However, nonlinear optical properties of 2D SCs have been investigated to a far lesser extent. It was shown in recent publications [14][15][16][17] that the nonlinear response of a SC of quantum emitters (QEs) with a ladder scheme [14][15][16] and Λ scheme of optical transitions [17] exhibits multistability, self-oscillations, and dynamic chaos. In addition, in a certain frequency range, the SC almost totally reflects the incident field, i.e., operates as an ideal nanometer-thick mirror, which, in addition, exhibits bistability.…”

Nonlinear Optical Dynamics and High Reflectance of a Monolayer of Three-Level Quantum Emitters with a Doublet in the Excited State

Multiple dynamics analysis of Lorenz-family systems and the application in signal detection

Reversible plasmonic switching in a graphene nanoresonator loaded with a core – shell quantum dot