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We report first observations of deterministic phase- and resonance-controlled all-optical analogue to electromagnetically induced transparency in coherently-coupled silicon photonic crystal nanocavities through thermo-optic tuning method, for realization of all-optical dynamical storage of light.
We observe experimentally all-optical analogue to electromagnetically induced transparency with silicon photonic crystal nanocavities having high intrinsic quality factor and small modal volume. This phenomenon is analyzed through coupled-mode formalism and three-dimensional finite-difference time-domain method.
We propose and demonstrate the digital resonance tuning of high-Q/Vm silicon photonic crystal nanocavities using self-limiting atomic layer deposition. Control of resonances of 122 ± 18 pm per hafnium oxide atomic layer is achieved.
We observe experimentally all-optical analogue to electromagnetically induced transparency with silicon photonic crystal nanocavities having high intrinsic quality factor and small modal volume. This phenomenon is analyzed through coupled-mode formalism and three-dimensional finite-difference time-domain method.
We propose and demonstrate the digital resonance tuning of high-Q/Vm silicon photonic crystal nanocavities using self-limiting atomic layer deposition. Control of resonances of 122 plusmn 18 pm per hafnium oxide atomic layer is achieved.
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