Abstract
This article exposes how we improved (by more than a factor of four) the green Lunar Laser Ranging instrumental sensitivity of the French telemetric station of the “Observatoire de la Côte d’Azur” in 2012. The primary reason for this success is the doubling of the pulse energy of our green Nd:YAG laser, reaching now 200mJ at 10Hz. This first gain is due to the replacement (inside our oscillator cavity) of the dye cell with a CR4+:YAG crystal saturable absorber. Complementary spatial beam profile improvements are also described, regarding polarisation, flashlamp geometry and specific lens arrangements (to exclude ghosts from focusing on the 8m long amplification chain). Those combined laser enhancements pave the way to future science breakthrough linked to quasi-millimetric determination of the Earth–Moon dynamics (Murphy, 2013). Jointly, we propose an empirical thermal lensing model, varying with the cycle ratio of the flashlamps. Our model connects Koechner’s (1970) continuous pumping to our intermittent pumping case, with a “normalised heating coefficient” equalling 0.05 only if the electrical lamp input power is equal to 6kW and scaling as this [electrical input power into the lamps] to the power of [half the pumping cycle ratio].
Highlights
Lasers are convenient remote sensors of distances, velocities, forces [3] or even chemical agents for various scientific applications ranging from civil engineering to astronomy
For a Nd:YAG rod An pumped by two lamps at a cycle ratio h, we propose to extend the Average thermal Focal Length of (16) to any value of h e ]0;1] with: AFL=1 kW 1⁄4 ðrAn=r0Þ2 Â ð1:65 m=PÞ=ðg=gK Þ; with g=gK 1⁄4 ðP=6 kWÞh=2
This study is focused on pulsed laser developments for the GRSM Lunar Laser Ranging station
Summary
This article exposes how we improved (by more than a factor of four) the green Lunar Laser Ranging instrumental sensitivity of the French telemetric station of the ‘‘Observatoire de la Côte d’Azur” in 2012. Complementary spatial beam profile improvements are described, regarding polarisation, flashlamp geometry and specific lens arrangements (to exclude ghosts from focusing on the 8 m long amplification chain). Those combined laser enhancements pave the way to future science breakthrough linked to quasi-millimetric determination of the Earth–Moon dynamics (Murphy, 2013). We propose an empirical thermal lensing model, varying with the cycle ratio of the flashlamps.
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