A. Saissy 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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Thermalization effects between upper levels of green fluorescence in Er-doped silica fibers

Maurice

Monnom

Dussardier

et al. 1994

Opt. Lett.

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We present a spectroscopic study of the green fluorescence resulting from pump excited-state absorption in Er-doped silica fibers excited in the 800-nm range. The absorption and emission bands are selectively attributed to the (4)S(3/2) and (2)H(11/2) levels. The fluorescence response at two excitation wavelengths, the temperature behavior, and lifetime measurements demonstrate a fast thermalization between the (4)S(3/2) and (2)H(11/2) levels. This explains an important part of the (2)H(11/2) emission and the increase of the fluorescence intensity at high temperature.

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High repetition rate passively Q -switched Nd ³⁺ :Cr ⁴⁺ all-fibre laser

et al. 2003

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A. Saissy

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

Thermalization effects between upper levels of green fluorescence in Er-doped silica fibers

High repetition rate passively Q -switched Nd ³⁺ :Cr ⁴⁺ all-fibre laser

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A. Saissy

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

Thermalization effects between upper levels of green fluorescence in Er-doped silica fibers

High repetition rate passively Q -switched Nd 3+ :Cr 4+ all-fibre laser

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High repetition rate passively Q -switched Nd ³⁺ :Cr ⁴⁺ all-fibre laser