Add to ORKGWe infiltrate liquid crystals doped with BaTiO3 nanoparticles in a photonic crystal fiber and compare the measured transmission spectrum to the one achieved with undoped liquid crystals. New interesting features such as frequency dependent behavior and a transmission spectrum with tunable attenuation on the short wavelength side of the bandgap suggest a potential application of this device as a tunable all-in-fiber gain equalization filter. The tunability of the device is demonstrated by changing the temperature of the liquid crystal and by varying both the amplitude and the frequency of the applied external electric field. © American Institute of Physics
In this study, we propose the fabrication and the electro-optical characterization of nanoparticle-b...
We present an electrically controlled photonic bandgap fiber device obtained by infiltrating the air...
We demonstrate a highly tunable photonic bandgap fiber, which has a large-core diameter of 25 μm and...
We infiltrate liquid crystals doped with BaTiO3 nanoparticles in a photonic crystal fiber and compar...
A tunable bandpass filter based on a Photonic Crystal Fiber filled with two different Liquid Crystal...
A tunable bandpass filter based on a Photonic Crystal Fiber filled with two different Liquid Crystal...
A tunable bandpass filter based on a photonic crystal fiber filled with two different liquid crystal...
A new class of hybrid photonic crystal fibers infiltrated with liquid crystals offers novel function...
Liquid crystal photonic bandgap fibers form a versatile and robust platform for designing optical fi...
Liquid crystal photonic bandgap fibers form a versatile and robust platform for designing optical fi...
The electronic tunability of ferroelectric liquid crystal filled photonic crystal fibres is demonstr...
Liquid crystal infiltrated photonic bandgap fibers form a versatile and robust platform for designin...
Liquid crystal photonic bandgap fibers represent a promising platform for the design of all-in-fiber...
We investigate the tunability of splay-aligned liquid crystals for the use in solid core photonic cr...
We present an electrically controlled photonic bandgap fiber device obtained by infiltrating the air...
In this study, we propose the fabrication and the electro-optical characterization of nanoparticle-b...
We present an electrically controlled photonic bandgap fiber device obtained by infiltrating the air...
We demonstrate a highly tunable photonic bandgap fiber, which has a large-core diameter of 25 μm and...
We infiltrate liquid crystals doped with BaTiO3 nanoparticles in a photonic crystal fiber and compar...
A tunable bandpass filter based on a Photonic Crystal Fiber filled with two different Liquid Crystal...
A tunable bandpass filter based on a Photonic Crystal Fiber filled with two different Liquid Crystal...
A tunable bandpass filter based on a photonic crystal fiber filled with two different liquid crystal...
A new class of hybrid photonic crystal fibers infiltrated with liquid crystals offers novel function...
Liquid crystal photonic bandgap fibers form a versatile and robust platform for designing optical fi...
Liquid crystal photonic bandgap fibers form a versatile and robust platform for designing optical fi...
The electronic tunability of ferroelectric liquid crystal filled photonic crystal fibres is demonstr...
Liquid crystal infiltrated photonic bandgap fibers form a versatile and robust platform for designin...
Liquid crystal photonic bandgap fibers represent a promising platform for the design of all-in-fiber...
We investigate the tunability of splay-aligned liquid crystals for the use in solid core photonic cr...
We present an electrically controlled photonic bandgap fiber device obtained by infiltrating the air...
In this study, we propose the fabrication and the electro-optical characterization of nanoparticle-b...
We present an electrically controlled photonic bandgap fiber device obtained by infiltrating the air...
We demonstrate a highly tunable photonic bandgap fiber, which has a large-core diameter of 25 μm and...