Growth, structure refinement, thermal expansion and optical spectroscopy of Tm3+-doped MgMoO4

Thulium-doped magnesium molybdate single-crystal (Tm3+:MgMoO4) was grown by the Czochralski method (melting point: 1322 degrees C). The actual Tm3+ doping level was measured to be 0.1 at.% (the segregation coefficient was only 0.02). Tm:MgMoO4 belongs to the monoclinic class (sp. gr. C2/m, lattice constants: a = 10.2769(2) angstrom, b = 9.2898(5) angstrom, c = 7.0269(4) angstrom, beta = 106.898(6)degrees). The thermal expansion tensor of this crystal is determined. Its thermal conductivity is also measured at 50-300 K (at room temperature, it amounts to 2.64 Wm- 1K-1). Polarized Raman spectra are presented and the strongest mode is found at 957 cm-1. Optical spectroscopy of Tm3+ ions is studied indicating broad emission bands extending beyond 2 mu m (the 3F4 -> 3H6 transition) and a long lifetime of the 3F4 excited-state (1.972 ms). This makes Tm:MgMoO4 promising for broadly tunable and mode-locked lasers, when the technological problem of fabricating crystals with higher Tm3+ concentrations will be solved.

Automated summary

Thulium-doped magnesium molybdate single-crystal (Tm3+:MgMoO4) with a Tm3+ doping level of 0.1 at.% was grown using the Czochralski method. The crystal belongs to the monoclinic class and has a thermal expansion tensor and thermal conductivity of 2.64 Wm- 1K-1. The optical spectroscopy of Tm3+ ions reveals broad emission bands and a long excited-state lifetime, making Tm:MgMoO4 a promising material for tunable and mode-locked lasers, pending the solution to the technological challenge of fabricating crystals with higher Tm3+ concentrations.