2.1

Manufacturing high-quality, high damage threshold coated Alexandrite laser crystals

The synthesis of single crystals is the starting point of manufacturing high-quality Alexandrite laser crystals and one of the most critical parts of the production chain. The Alexandrite laser crystals produced within the scope of the GALACTIC project are grown using the Czochralski method. The Czochralski method is one of the most utilized techniques for synthesizing inorganic single crystals and guarantees the possibility to extend a product from a laboratory environment to mass production with a high level of reproducibility. A detailed explanation of this method is given in literature^13,14. To reach a high TRL, the quality of available crystals has to be improved by determining the best experimental conditions for a low number of defects – i.e. minimizing bubbles, defect sites and cracks – and low mechanical stress, while ensuring a reproducible manufacturing process of the products. For that, several crystal boules will be synthesized with modified growth parameters, e.g. gas pressure, pulling and rotation speed and doping concentration. Afterwards, they will be characterized regarding their optical and spectroscopic properties e.g. by measuring the absorption and transmittance. Furthermore, the physical properties, such as the size and tolerances, geometric profile and angular shaping, parallelism, perpendicularity, interferometric wavefront distortion, surface flatness, curvature and surface quality (scratch/dig), barrel finish and bevels, are verified. Lattice and vibrational characterization by X-ray and Raman spectroscopy are also performed to validate the correct crystal phase and monitor the crystal structure’s stress and deformation.

Figure 1:

a) Sketch of the Czochralski crystal growth method; b) Example of an Alexandrite crystal boule.

The last steps in the optical element production are the crystal surface pre-treatment prior to coating deposition and the coating deposition itself. Therefore, defects such as scratches, digs, microcracks and residual polishing compounds, which are induced by or remaining after the polishing process, have to be removed by optimization of the surface pre-treatment process¹⁵. To obtain high LIDT values, the pre-treatment process must substantially reduce these scratches and subsurface defects. Therefore, several crystal pre-treatment experiments will be carried out, including different ultrasonic cleaning procedures and radio frequency (RF) plasma etching with different types of ions, varying etching rates and depths (see “ClusterLineRAD” shown in Figure 2). This etching procedure has tenfold increased the LIDT of commercial polished fused silica substrates and has cleaned out the subsurface damages¹⁶. Hence, also a significant increase of the LIDT of the Alexandrite crystals can be expected.

Figure 2:

Schematic diagram (left) and ClusterLine RAD sputter platform (right) showing etching procedure.

After a successful pre-treatment of the crystals’ end facets, two different state-of-the-art deposition techniques will be used for coating the crystals with anti-reflective (AR) and high-reflective (HR) coatings, namely ion beam sputtering (IBS) and reactive magnetron sputtering (RMS). Thereby, the variation of the deposition technology and the coating materials will lead to the best candidates for coating the Alexandrite crystals for space applications (see Table 2). Two sets of optical interference coatings on both end surfaces of the crystal will be designed and realized, whose specifications are listed in Table 3. To finalize the coating process, the optical coatings will be tested regarding transmission, reflection and absorption properties, the resistance to laser radiation (LIDT test), the adhesion strength and durability (tape-lift test) and finally, the laser performance in the demonstrator systems developed within the project.

Table 2:

Variation of deposition technologies and coating materials explored in this project.

Table 3:

Two designs of optical interference coatings.

2.2

Laser demonstrator systems

Two laser demonstrators will be set up within the GALACTIC project with the focus on the development, assembly and testing of breadboard-level Alexandrite laser systems with two different operational regimes. Both demonstrator setups are designed to test and verify the laser crystal related functional limitations that are influenced by the overall laser crystal and coating manufacturing process. The systems are derived from two typical applications of remote sensing: atmospheric space-based LIDAR and altimetry or vegetation monitoring. For atmospheric sensing from a satellite-based platform, e.g. wind or resonant backscatter LIDAR systems, high laser pulse energies in the range of multi ten mJ are required because of the low signal return. Pulse durations can be long in the range of multi ten up to around ~100 ns^4,17. Satellite-based lasers for vegetation monitoring require less laser pulse energy because of the better signal return from the ground compared with the signal return in atmospheric sensing applications. Here, short pulses in the nanosecond range are necessary (e.g. a pulse duration of 1 ns corresponds to a roundtrip resolution of 15 cm in height profiling). Besides, a higher pulse repetition rate (multi-kHz) compared to atmospheric sensing (> 150 Hz) is desirable for a good lateral spatial resolution and a high sampling rate⁴. The design driving laser parameters pulse energy and pulse repetition rate can therefore be split into two regimes. The first demonstrator will reach a high pulse energy at a low repetition rate and will be realized by an actively q-switched Alexandrite laser system (see Figure 3 a). The second demonstrator, consisting of a cavity-dumped and actively q-switched Alexandrite laser system (see Figure 3 b), will be realized with low pulse energy but with a high repetition rate.

Figure 3:

a) high pulse energy - low repetition rate laser demonstrator system; b) low pulse energy - high repetition rate laser demonstrator system. Abbreviations: BS = Beam splitter, M = Mirror, PO = Pump optics, IC = Input coupler, BM = Bending mirror, OC = Output coupler, BFF = Birefringent filter, TFP = Thin film polarizer, HR = Highly reflecting mirror.

The intended laser output parameters to be realized in both systems at the end of the project are summarized in Table 4. The parameters are derived from the laser requirements of the two applications of space-based remote sensing.

Table 4:

Intended laser output parameters of the demonstrator setups within the GALACTIC project.

3.1

Temperature cycling tests

To define the thermal cycling test conditions for TRL 6 verification, typical mission temperature requirements, laser material characteristics, the MIL-C-48497A¹⁸ (“Requirements for coating durability”) norm and internal testing standards for high-quality optical components are considered. Due to the material characteristics of Alexandrite, two different derivations were used to specify the lower and the upper thermal cycling limit.

The efficiency of Alexandrite can be optimized by operating the crystals at elevated temperatures around 100 °C⁶. This value is far beyond typical maximum non-operational temperatures for space-based laser systems. Because of this specific characteristic, the maximum temperature is defined by the expected operational limit plus a sufficiently high margin instead of applying a typical maximum non-operational temperature. For the lower thermal cycling limit, literature values are consulted. Typical temperature test ranges for LEO missions have been reported e.g. for the GLAS laser as part of the LEO Earth observation ICESat¹⁹ as well as the ATLAS instrument for ICESat-2 (0 °C up to +50 °C)²⁰, for the ALADIN laser onboard the ADM-Aeolus mission (-15 °C up to +50 °C)²¹ and for the FULAS laser developed for a future high power space-based LIDAR system (-30 °C up to +50 °C)²². Thus, the test parameters for the thermal cycling within the GALACTIC project result as follows:

Thermal durability tests are carried out in a climatic chamber (ESPEC SH-262) with non-condensing, dry conditions setting no humidity (see Figure 5 b).

Figure 5.

a) Thermal cycling test sequence (schematic); b) Climatic chamber (ESPEC SH-262) for thermal durability tests.

3.2

Gamma and proton irradiation tests

The radiation environment relevant for LEO missions is dominated by high energetic charged particles trapped in the inner van-Allen belt. Radiation tests with optical components for space missions are typically performed separately on the one hand with protons for considering Total Non-Ionizing Dose (TNID) effects (displacement damages) and on the other hand with gamma radiation for Total Ionizing Dose (TID) effects. Co-60 sources providing gamma radiation with characteristic energies of 1.173 MeV and 1.332 MeV are typically used for TID testing, whereas proton beams usually generated in cyclotrons are used for TNID testing.

In literature, a typical gamma irradiation dose of 1-2 krad per year for a LEO orbit assuming a 4 mm aluminium shielding²³, a total gamma dose of 5-10 krad for laser systems for LIDAR applications²⁴ and 30 krad for the GLAS as well as the ATLAS laser^19,20 development is reported. Therefore, the parameters for the gamma radiation test to be applied within GALACTIC are:

The gamma radiation test will be performed with two total dose levels to cover uncertainties because no specific space mission for Alexandrite lasers has been defined yet.

Regarding the total proton flux relevant for LEO missions, the literature²⁴ reports a range of 10¹¹ protons/cm² to 10¹² protons/cm². Furthermore, proton irradiation tests with non-linear optical crystals were performed with proton energies of 8, 70 and 300 Mev²⁵. If the proton irradiated test item is susceptible to displacement damage, what is unknown for Alexandrite laser crystals, several proton energies up to 200 MeV should be tested²⁴. Here, the used test parameters for the proton radiation tests will be

Different parts will be used to test the two gamma radiation dose levels and the two proton energies.