Nonlinearity and nonclassicality in single-qubit laser operation

“…[65] The Jaynes-Cummings model gave rise to a plethora of important theoretical predictions and experimental observations, such as, for example, Rabi splitting, [66][67][68] antibunching and sub-Poissonian statistics of the intra-cavity field, [69,70] phase and amplitude bistability; [71,72] a variable source for conditional and unconditional generation of non-classical states. [73][74][75][76][77] However, up to this date there are no experiments demonstrating "collapses" and "revivals" due to atomic interaction with a single-mode field in a non-Gaussian non-classical state. In particular, specific "structured revivals" were predicted for the initial state given by Equation (26).…”

“…[ 65 ] The Jaynes‐Cummings model gave rise to a plethora of important theoretical predictions and experimental observations, such as, for example, Rabi splitting, [ 66–68 ] antibunching and sub‐Poissonian statistics of the intra‐cavity field, [ 69,70 ] phase and amplitude bistability; [ 71,72 ] a variable source for conditional and unconditional generation of non‐classical states. [ 73–77 ]…”

Classical Emulation of Bright Quantum States

“…[65] The Jaynes-Cummings model gave rise to a plethora of important theoretical predictions and experimental observations, such as, for example, Rabi splitting, [66][67][68] antibunching and sub-Poissonian statistics of the intra-cavity field, [69,70] phase and amplitude bistability; [71,72] a variable source for conditional and unconditional generation of non-classical states. [73][74][75][76][77] However, up to this date there are no experiments demonstrating "collapses" and "revivals" due to atomic interaction with a single-mode field in a non-Gaussian non-classical state. In particular, specific "structured revivals" were predicted for the initial state given by Equation (26).…”

“…[ 65 ] The Jaynes‐Cummings model gave rise to a plethora of important theoretical predictions and experimental observations, such as, for example, Rabi splitting, [ 66–68 ] antibunching and sub‐Poissonian statistics of the intra‐cavity field, [ 69,70 ] phase and amplitude bistability; [ 71,72 ] a variable source for conditional and unconditional generation of non‐classical states. [ 73–77 ]…”

Classical Emulation of Bright Quantum States

“…Also, it has been successfully applied to the study of input-output relation for anisotropic magnetodielectric multilayer structures [10], the spontaneous emission [11,12], nonlinear magnetodielectric media [13,14], moving media [15], and the Casimir effect [16]. Since nonclassical states are an important prerequisite for different tasks of quantum information processing, such as quantum cryptography, quantum computing, quantum voting [17], in the present paper, we utilize the above-mentioned rigorous canonical approach to study the behavior of a nonclassical state (nonlinear coherent state on a sphere) in passing through a dielectric slab. From this point of view, nonlinear coherent states which possess prominent nonclassical properties are good candidates for examination by transmission through a dielectric medium.…”

Scattering of sphere coherent state by an absorptive and dispersive dielectric slab

Phase-space dynamics of a single-atom laser: Nonclassicality and bistability