Abstract:
In this thesis, we study a system consisting of qubits—two-level quantum systems— interacting in the strong-coupling regime for a finite amount of time with a mode of the electromagnetic field inside a resonator. In particular, we are interested in the dynamics of the photon number and the possibility of controlling its statistics to produce sub-Poissonian light. To describe the system we use quantum trajectory theory where the time evolution of the state vector consists of both a continuous part and jumps, which account for the resonator losses. We also incorporate a variable number of qubits (changing in time) interacting with the mode. A computer simulation was developed and optimised to calculate the quantum trajectories. When one sets the qubits initially to the excited state and fixes the interaction time accordingly, so-called “trapping states” (photon numbers which block the addition of a photon by a single qubit) appear. These states are instrumental in the generation of sub-Poisson fields, for some cases even when the number of interacting qubits follow a Poisson process. We take advantage of the existence of trapping states to implement control protocols based on the measurement of the output field of the resonator, with the objective of lowering the uncertainty in the number of photons. Furthermore, we explore the possibility of creating a source of sub-Poissonian pulses by first using a random interaction time (which bypasses the trapping states) and then utilising the control protocols developed. We are able to achieve fields with a Mandel Q parameter of QM = −0.98 and a photon number of n 68.