We introduce the basic physical mechanisms governing a semiconductor heterostructure-based microresonator: e.g. the carrier density dynamics coupled to the diffractive dynamics of the field, a proper modelization of the mutual nonlinear interaction, and the carrier diffusion. Although diffusion is normally an anti-patterning effect, and even in presence of self-defocusing nonlinearities (typical of passive devices), we can predict extended and experimentally achievable regimes where spatial solitons are stable.
Cavity solitons in semiconductor microresonators
Spinelli L;
1999
Abstract
We introduce the basic physical mechanisms governing a semiconductor heterostructure-based microresonator: e.g. the carrier density dynamics coupled to the diffractive dynamics of the field, a proper modelization of the mutual nonlinear interaction, and the carrier diffusion. Although diffusion is normally an anti-patterning effect, and even in presence of self-defocusing nonlinearities (typical of passive devices), we can predict extended and experimentally achievable regimes where spatial solitons are stable.File in questo prodotto:
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