The paper deals with spectral and lasing characteristics of
thulium-doped optical fibers fabricated by means of two doping
techniques,
i.e. via a conventional solution-doping method and via
a nanoparticle-doping method. The difference in fabrication was the
application of a suspension of aluminum oxide nanoparticles of defined
size instead of a conventional chloride-containing solution. Samples of
thulium-doped silica fibers having nearly identical chemical composition
and waveguiding properties were fabricated. The sample fabricated by
means of the nanoparticle-doping method exhibited longer lifetime,
reflecting other observations and the trend already observed with the
fibers doped with erbium and aluminum nanoparticles. The fiber
fabricated by means of the nanoparticle-doping method exhibited a lower
lasing threshold (by ~20%) and higher slope efficiency (by ~5% rel.).
All these observed differences are not extensive and deserve more
in-depth research; they may imply a positive influence of the
nanoparticle approach on properties of rare-earth-doped fibers for fiber
lasers.
We demonstrated two methods of increasing the bandwidth of a broadband light source based on amplified spontaneous emission in thulium-doped fibres. Firstly, we have shown by means of a comprehensive numerical model that the full-width at half maximum of the thulium-doped fibre based broadband source can be more than doubled by using specially tailored spectral filter placed in front of the mirror in a double-pass configuration of the amplified spontaneous emission source. The broadening can be achieved with only a small expense of the output power. Secondly, we report results of the experimental thulium-doped fibre broadband source, including fibre characteristics and performance of the thulium-doped fibre in a ring laser setup. The spectrum broadening was achieved by balancing the backward amplified spontaneous emission with back-reflected forward emission.