Microscopic theory of squeezed light in quantum-dot systems

We present a cavity-QED theory for generating squeezed light from semiconductor quantum dots (QDs) integrated in microcavities.We formulate equations of motion for an inhomogeneously broadened QD ensemble that is incoherently pumped and simultaneously driven by a coherent seed field, solve for steady states, and compute the output-field quadrature variances. The analysis identifies operating conditions that yield amplitudequadrature squeezing, with photon-number fluctuations reduced below the coherent-state limit and squeezing levels as large as 5 dB attainable with presently accessible QD and cavity parameters using only ∼1 μW pump power. We further show that quantum correlations originating from four-wave mixing play a dual role: they both shape the gain spectrum and generate squeezing. These correlations constitute the quantum counterpart of the mean-field (semiclassical) mechanisms responsible for self-mode locking in QD lasers and the ultranarrow lasing linewidths achieved under self-injection locking.