Gérard Monnom scite author profile

The variation in the green intensity ratio ((2)H(11/2) and (4)S(3/2) energy levels to the ground state) of Er ions in silica fibers has been studied as a function of temperature. The different processes that are used to determine the population of these levels are investigated, in particular 800-nm excited-state absorption in Er-doped fibers and 980-nm energy transfer, in Yb-Er-codoped fibers. The invariance of the intensity ratio at a fixed temperature with respect to power, wavelength, and doped fiber length has been investigated and shown to permit the realization of a high-dynamic-range (greater than 600 °C), autocalibrated fiber-optic temperature sensor.

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Conception, Realization, and Characterization of a Very High Negative Chromatic Dispersion Fiber

Auguste

Blondy

Maury

et al. 2002

Optical Fiber Technology

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Visible and near infra-red up-conversion in Tm^3+/Yb^3+ co-doped silica fibers under 980 nm excitation

Simpson¹,

Gibbs²,

Collins³

et al. 2008

Opt. Express

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The spectroscopic properties of Tm(3+)/Yb(3+) co-doped silica fibers under excitation at 980 nm are reported. Three distinct up-conversion fluorescence bands were observed in the visible to near infra-red regions. The blue and red fluorescence bands at 475 and 650 nm, respectively, were found to originate from the (1)G(4) level of Tm(3+). A three step up-conversion process was established as the populating mechanism for these fluorescence bands. The fluorescence band at 800 nm was found to originate from two possible transitions in Tm(3+); one being the transition from the (3)H(4) to (3)H(6) manifold which was found to dominate at low pump powers; the other being the transition from the (1)G(4) to (3)H(6) level which dominates at higher pump powers. The fluorescence lifetime of the (3)H(4) and (3)F(4) levels of Tm(3+) and (2)F(5/2) level of Yb(3+) were studied as a function of Yb(3+) concentration, with no significant energy back transfer from Tm(3+) to Yb(3+) observed.

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–1800 ps/(nm.km) chromatic dispersion at 1.55µm in dual concentric core fibre

Auguste

Jindal²,

Blondy

et al. 2000

Electron. Lett.

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Gérard Monnom

Erbium-doped silica fibers for intrinsic fiber-optic temperature sensors

Conception, Realization, and Characterization of a Very High Negative Chromatic Dispersion Fiber

Visible and near infra-red up-conversion in Tm^3+/Yb^3+ co-doped silica fibers under 980 nm excitation

–1800 ps/(nm.km) chromatic dispersion at 1.55µm in dual concentric core fibre

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