A laser with short pulse width and direct output of a vortex beam was reported herein. This laser was fabricated from a nonlinear loop mirror (NOLM) and a coupler composed of a single mode fiber and few-mode fiber fused together. The NOLM is responsible for generating pulses, and the coupler acts as a beam splitter and mode converter. Two stable vortex modes can be formed by adjusting the polarization controller, whose pulse widths are 1.098 ps and 542 fs, respectively.
A broadband highly dispersive fiber based on a dual-concentric-core photonic quasicrystal fiber (PQF) is designed for chromatic dispersion compensation. The fiber is composed of pure silica background and air-holes without doping. The fundamental supermode has a large negative dispersion value of about −9600 ps•nm −1 •km −1 over an optical communication band around 1550 nm and a full width at half maximum (FWHM) of 40 nm. By adjusting the structural parameters, a dispersion of −2250 ps•nm −1 •km −1 around 1550 nm with the FWHM exceeding 280 nm is obtained and the dispersion-bandwidth product can reach 630 GHz −1 •km −1 , which is the highest value of dispersion-bandwidth product from pure silica fibers reported so far.
Two narrow‐linewidth Yb3+‐doped double‐clad fiber‐laser cavities based on double‐clad fiber Bragg gratings are presented. One is an all‐fiber cavity, the other one is based on a dichroic mirror and Moiré grating. The fiber Bragg gratings have been formed in Yb3+‐doped double‐clad fiber using the phase‐mask method. © 2004 Wiley Periodicals, Inc. Microwave Opt Technol Lett 44: 53–56, 2005; Published online in Wiley InterScience (www.interscience.wiley.com). DOI 10.1002/mop.20545
In an optical fiber communication system, vortex beams have aroused great interest in the last several decades. Vortex beams possess many intriguing properties. For example, they have the ability to carry orbital angular momentum (OAM) which is mutually orthogonal. The OAM is a fundamental physical quantity of light which can be used as information carriers for transmission channel of optical fiber. Combined with the existing multiplexing techniques such as wavelength division multiplexing technique, advanced multilevel amplitude modulation formats, etc., the vortex beams provide an alternative to the increase of the transmission capacity and spectral efficiency of the optical fiber transmission system. Recently, long-length transmission of vortex-beam in optical fiber has been realized and there have also occurred some new designs of optical fiber on vortex beams, such as air-core ring shaped fiber, graded index vortex fiber, multi-ring fiber, and supermode fiber. Photonic crystal fiber (PCF) is flexible in design. Therefore, it is easy to regulate the transmission performance of PCF by adjusting the radius and the pitch of the air holes and so on. In this paper, we propose a newly designed sixfold photonic quasi-crystal fiber (SPQCF) to transmit vortex beams stably. Transmission characteristics of this newly designed fiber are simulated and calculated by using COMSOL multiphysics software. When the wavelength of the incident light is 1550 nm, the effective index difference between the vortex modes in a group is more than 10<sup>–4</sup> which is large enough to preclude the LP modes from being formed, and to transmit 7 vector modes (10 OAM modes). Changing the radius and pitch of the air holes, we can regulate the dispersion characteristic and confinement loss of the SPQCF flexibly. At 1550 nm, the confinement loss of the SPQCF maintains 10<sup>–8</sup>−10<sup>–7</sup> which is low enough to confine the vortex beams in the fiber core. When the incident light wavelength of HE<sub>21</sub> ranges from 1500 nm to 1800 nm (<i>r</i><sub>0</sub> = 1.9 μm), the dispersion coefficient of the SPQCF is between 63.51−65.42 ps·nm<sup>–1</sup>·km<sup>–1</sup> which tends to be flat. By changing <i>r</i><sub>0</sub>, the flat trend is adjusted to different wavelength range. This dispersion characteristic possesses great potential for the transmission of optical solitons. The effective mode area (HE<sub>21</sub>) is about 40 μm<sup>2</sup> and the nonlinear coefficient (HE<sub>21</sub>) is maintained on the order of 10<sup>–3</sup> between 1500−1600 nm. These features suppress the generation of nonlinear effect in the fiber and benefit the transmission of vortex beams. The stable transmission distance is longer than 1 km. In summary, we design a new type of PCF featuring quasi-crystal structure which has a ring shaped fiber core and supports the transmission of vortex beams stably.
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