Title :
Cavity solitons in semiconductor microresonators
Author :
Brambilla, M. ; Maggipinto, T. ; Perrini, I. ; Spinelli, L. ; Tissoni, G. ; Lugiato, L.
Author_Institution :
Dipt. di Fisica, Bari Univ., Italy
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
Keywords :
micro-optics; micromechanical resonators; optical resonators; optical self-focusing; optical solitons; stability; anti-patterning effect; carrier density dynamics; carrier diffusion; cavity solitons; diffractive dynamics; mutual nonlinear interaction; passive devices; physical mechanisms; self-defocusing nonlinearities; semiconductor heterostructure-based microresonator; semiconductor microresonators; stable spatial solitons; Microcavities; Nonlinear optics; Optical beams; Optical control; Optical devices; Optical feedback; Optical modulation; Optical propagation; Optical resonators; Optical solitons;
Conference_Titel :
Transparent Optical Networks, 1999. International Conference on
Conference_Location :
Kielce
Print_ISBN :
0-7803-5637-3
DOI :
10.1109/ICTON.1999.781865
