Microstructured optical fibers make for a versatile photonic platform which combines tailored optical mode propagation properties with microfluidic functionality. For instance, microfluidic channels running through a fiber can permit the movement of small plugs of liquid whose own optical properties alter the passage of light in a controllable way. A report published in the July 1 issue of Optics Letters (DOI:10.1364/OL.36.002548, p. 2548) demonstrates how this emerging technology can employ magnetosensitive liquids to create optical fiber devices whose spectral transmission is tunable with a magnetic field.
S. Pissadakis and his team from the Foundation for Research and Technology, Institute of Electronic Structure and Laser, in Greece, developed these magnetofluidic devices in collaboration with the group of W. Margulis from Acreo AB in Sweden, which fabricated silicate optical fibers incorporating five axial microfluidic channels. Using deep ultraviolet laser radiation, they inscribed a 2.4 cm length of the fiber with a region of alternating refractive index known as a Bragg grating, which reflects and transmits specific wavelengths of light.
A “ferrofluid” dispersion of magnetite (Fe3O4) nanoparticles in an isoparrafinic solvent was infiltrated into the microfluidic channels as a 2 mm long plug which acts as a phase defect when overlapping with the grating. This shows up as a dip in the reflected bandwidth whose position and magnitude can be altered by using an external magnetic field to displace the fluid.
A more powerful effect was seen when applying the same principle to a “chirped” Bragg grating, which includes a linear variation in the period of the alternating refractive index. In this case, the ferrofluid plug causes an asymmetrical chopping of the Bragg grating reflected spectrum, narrowing the bandwidth and shifting it to higher wavelengths. In this instance, the sections of grating on either side of the plug are no longer in resonance, and therefore only the illuminated side interacts with the reflected spectrum.
“Such magnetofluidic optical fiber components could be the precursors to developing ultracompact and high-performance photonic devices, serving diverse sensing applications in medicine and electrical power delivery,” Pissadakis said.