We introduce a computational Maxwell-Bloch framework for investigating out of
equilibrium optical emitters in open cavity-less systems. To do so, we compute
the pulse-induced dynamics of each emitter from fundamental light-matter
interactions and self-consistently calculate their radiative coupling,
including phase inhomogeneity from propagation effects. This semiclassical
framework is applied to open systems of quantum dots with different density and
dipolar coupling. We observe that signatures of superradiant behavior, such as
directionality and faster decay, are weak for systems with extensions
comparable to λ/2. In contrast, subradiant features are robust and can
produce long-term population trapping effects. This computational tool enables
quantitative investigations of large optical ensembles in the time domain and
could be used to design new systems with enhanced superradiant and subradiant
properties.Comment: 5 pages, 5 figure