Spatio-temporal modulation has shown great promise as a strong time-reversal
symmetry breaking mechanism that enables integrated nonreciprocal devices and
topological materials at optical frequencies. However, optical modulation has
its own constraints in terms of modulation index and frequency, which limit the
bandwidth and miniaturization of circulators and isolators, not unlike the
magneto-optical schemes that it promises to replace. Here we propose and
numerically demonstrate a Floquet circulator that leverages the untapped
degrees of freedom unique to time-modulated resonators. Excited by
sideband-selective waveguides, the system supports broadband nonreciprocal
transmission without relying on the mirror or rotational symmetries required in
conventional circulators. Cascading two resonators, we create a linear
three-port circulator that exhibits complete and frequency-independent forward
transmission between two of the ports. This approach enables wavelength-scale
circulators that can rely on a variety of modulation mechanisms