Optical fiber poling by induction: analysis by 2D numerical modeling
Optics Letters, 2016•opg.optica.org
Since their first demonstration some 25 years ago, thermally poled silica fibers have been
used to realize device functions such as electro-optic modulation, switching, polarization-
entangled photons, and optical frequency conversion with a number of advantages over
bulk free-space components. We have recently developed an innovative induction poling
technique that could allow for the development of complex microstructured fiber geometries
for highly efficient χ^(2)-based device applications. To systematically implement these more …
used to realize device functions such as electro-optic modulation, switching, polarization-
entangled photons, and optical frequency conversion with a number of advantages over
bulk free-space components. We have recently developed an innovative induction poling
technique that could allow for the development of complex microstructured fiber geometries
for highly efficient χ^(2)-based device applications. To systematically implement these more …
Since their first demonstration some 25 years ago, thermally poled silica fibers have been used to realize device functions such as electro-optic modulation, switching, polarization-entangled photons, and optical frequency conversion with a number of advantages over bulk free-space components. We have recently developed an innovative induction poling technique that could allow for the development of complex microstructured fiber geometries for highly efficient χ^(2)-based device applications. To systematically implement these more advanced poled fiber designs, we report here the development of comprehensive numerical models of the induction poling mechanism itself via two-dimensional (2D) simulations of ion migration and space-charge region formation using finite element analysis.
opg.optica.org
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