Abstract
Optical localized states are usually defined as self-localized bistable packets of light, which exist as independtly controllable optical intensity pulses either in the longitudinal [1] or transverse [2] dimension of nonlinear optical systems. Here we demonstrate experimentally and analytically the existence of longitudinal localized states that exist fundamentally in the phase of laser light. These robust and versatile phase bits can be individually nucleated and canceled in an injection-locked semiconductor laser operated in a neuron-like excitable regime and submitted to delayed feedback. The demonstration of their control opens the way to their use as phase information units in next-generation coherent communication systems. We analyse our observations in terms of a generic model, which confirms the topological nature of the phase bits and discloses their formal but profound analogy with Sine–Gordon solitons.
© 2015 IEEE
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