Title :
Simulation of fiber fuse phenomenon in single-mode optical fibers
Author :
Shuto, Yoshito ; Yanagi, Shuichi ; Asakawa, Shuichiro ; Kobayashi, Masaru ; Nagase, Ryo
Author_Institution :
Photonics Labs., NTT Corp., Atsugi, Japan
Abstract :
The unsteady-state thermal conduction process in single-mode (SM) optical fiber was studied theoretically with the explicit finite-difference method (FDM). In the numerical calculation it was assumed that the electrical conductivity of the core layer increased rapidly above 1323 K. The core-center temperature changed suddenly and reached over 3×105 K when an optical power of 1 W was input into the core layer heated at 1373 K. This rapid heating of the core initiated the "fiber fuse" phenomenon. The high-temperature core areas, whose radiation spectrum extended over a wide range from the infrared to the ultraviolet regions, were enlarged and propagated toward the light source at a rate of about 0.7 m s-1. This rate was in fair agreement with the experimentally determined value.
Keywords :
finite difference methods; heat conduction; light absorption; optical fibre theory; thermo-optical effects; 1323 K; 1373 K; core-center temperature; explicit finite-difference method; fiber fuse phenomenon; nonlinear phenomena; rapid heating; single-mode optical fiber; spectral emissive power; thermally induced optical-power absorption; unsteady-state thermal conduction; Finite difference methods; Fuses; Infrared spectra; Light sources; Optical fibers; Optical propagation; Rapid thermal processing; Samarium; Temperature; Thermal conductivity;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2003.819142
