Abstract
In this work, we demonstrate for the first time the capability to inscribe long-period gratings (LPGs) with UV radiation using simple and low cost amplitude masks fabricated with a consumer grade 3D printer. The spectrum obtained for a grating with 690 µm period and 38 mm length presented good quality, showing sharp resonances (i.e., 3 dB bandwidth < 3 nm), low out-of-band loss (~0.2 dB), and dip losses up to 18 dB. Furthermore, the capability to select the resonance wavelength has been demonstrated using different amplitude mask periods. The customization of the masks makes it possible to fabricate gratings with complex structures. Additionally, the simplicity in 3D printing an amplitude mask solves the problem of the lack of amplitude masks on the market and avoids the use of high resolution motorized stages, as is the case of the point-by-point technique. Finally, the 3D printed masks were also used to induce LPGs using the mechanical pressing method. Due to the better resolution of these masks compared to ones described on the state of the art, we were able to induce gratings with higher quality, such as low out-of-band loss (0.6 dB), reduced spectral ripples, and narrow bandwidths (~3 nm).
Highlights
The capability of manipulating the properties of light propagation inside an optical fiber can be achieved using different fiber optic technologies
The transmission spectra of the long-period gratings (LPGs) produced for the different amplitude masks periods are found on Figure 9a, while the dip wavelength associated each attenuation band isare shown as on a function of while the grating peproduced for the differenttoamplitude masks periods found
In this work we have demonstrated the ability to and inexpensively fabricate amplitude masks through a consumer grade 3D printer, allowing to create LPGs, through the UV scanning method and by the mechanical pressing method
Summary
The capability of manipulating the properties of light propagation inside an optical fiber can be achieved using different fiber optic technologies. The fabrication of these gratings has been made by irradiating the fiber through an amplitude mask [1,7,21,22], or point-by-point (PbP) along its length [23] While the latter technique offers flexibility to control the grating period and length, allowing us to produce different kinds of LPG profiles, it requires the use of a high resolution motorized stage, electronic shutter, and longer inscription time. While the first offers more control on the grating properties, both technologies are suited for mass production of multiple LPGs. Literature review on the types of amplitude masks reported so far shows the existence of four types, namely: Chrome-on-silica masks [1], patterned mirror (dielectric masks) [22], metal masks [4,5,23], e.g., Cu vapor laser milling of a copper foil [5], and microlens array [24].
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
