Bi-doped SiO2 as a new laser material for an intense laser

“…The bigger the products, the better the bandwidth and gain properties of the amplifiers. The parameters of r em · FWHM and r em · s for the GAB glass are about 499 · 10 À20 cm 2 nm and 4.23 · 10 À24 cm 2 s, respectively, which are bigger than that for Er 3+ -doped silicate glass (r em · FWHM = 22 · 10 À20 cm 2 nm) [29], that for Cr-doped foresterite (r em · s = 2.85 · 10 À24 cm 2 s) [11] and that for Ti-doped sapphire (r em · s = 1.4 · 10 À24 cm 2 s) [6]. Therefore, it can be suggested from the above comparison that the Bi-and Al-co-doped germanium oxide glass might be the promising host material for the super-broadband amplifiers.…”

“…The stimulated emission cross-section (r em ) at 1280 nm was estimated to be 1.55 · 10 À20 cm 2 by Fü chtbauerLandenburg equation: r em ¼ k 4 8pn 2 cÁDk Á 1 s rad Á gðkÞ where k is wavelength, g(k) is the normalized spontaneous emission shape function, n is the host refractive index, c is light velocity, Dk is the FWHM of emission and s rad is the emission lifetime [11]. In this work, Dk = 322 nm, s rad = 273 ls and n = 1.6166, respectively for GAB glass.…”

Investigations on bismuth and aluminum co-doped germanium oxide glasses for ultra-broadband optical amplification

“…The bigger the products, the better the bandwidth and gain properties of the amplifiers. The parameters of r em · FWHM and r em · s for the GAB glass are about 499 · 10 À20 cm 2 nm and 4.23 · 10 À24 cm 2 s, respectively, which are bigger than that for Er 3+ -doped silicate glass (r em · FWHM = 22 · 10 À20 cm 2 nm) [29], that for Cr-doped foresterite (r em · s = 2.85 · 10 À24 cm 2 s) [11] and that for Ti-doped sapphire (r em · s = 1.4 · 10 À24 cm 2 s) [6]. Therefore, it can be suggested from the above comparison that the Bi-and Al-co-doped germanium oxide glass might be the promising host material for the super-broadband amplifiers.…”

“…The stimulated emission cross-section (r em ) at 1280 nm was estimated to be 1.55 · 10 À20 cm 2 by Fü chtbauerLandenburg equation: r em ¼ k 4 8pn 2 cÁDk Á 1 s rad Á gðkÞ where k is wavelength, g(k) is the normalized spontaneous emission shape function, n is the host refractive index, c is light velocity, Dk is the FWHM of emission and s rad is the emission lifetime [11]. In this work, Dk = 322 nm, s rad = 273 ls and n = 1.6166, respectively for GAB glass.…”

Investigations on bismuth and aluminum co-doped germanium oxide glasses for ultra-broadband optical amplification

“…However Bi 3+ cannot emit the IR fluorescence [9]. Fujimoto et al [6,7] reported that the origin of IR fluorescence would be Bi 5+ . According to our results, higher valency state Bi 5+ would be impossible to form such reducing conditions: low basicity of matrix composition and high melting temperature.…”

“…On the other hand, Fujimoto et al [6,7] discovered that IR fluorescence of aluminosilicate glasses containing with the Bi 2 O 3 . This IR fluorescence shows broad bands around 1200 nm at room temperature without any crystalline phases.…”

Matrix effect on absorption and infrared fluorescence properties of Bi ions in oxide glasses

“…The IR luminescence of bismuth centers discovered in Al 2 O 3 -SiO 2 :Bi glasses [1,2] has been observed in various glasses and crystals. Despite active studies of the bismuth-related IR luminescence (the present state of the art is reviewed in [3]) and successful applications for laser amplification and generation (see e.g.…”

Origin of near-IR luminescence in Bi_2O_3–GeO_2 and Bi_2O_3–SiO_2 glasses: first-principle study