The Optics Bench

The laser and optics sub-system concept is shown in Fig.2, it consists of a DFB laser diode source, laser light polarization management and optical power distribution into three light-atom interaction zones. The over-all physically necessary power is 5mW of laser light locked to the Cs D1 4-3’ transition at 894nm [3]. The laser diode collimation lens is implemented using dynamic alignment and low-retraction glue. Although the expected lifetime of the laser diodes exceeds the system lifetime, two laser sources are mounted in cold redundancy. A polarization asymmetry is introduced between the two laser diodes for this purpose. Indeed, the laser light is spatially depolarized for the interaction with the Cs atoms. As such, any linear seed polarization is acceptable. In contrast to a 50/50 beam-splitter redundancy, this approach leads to a lower required laser diode optical power increasing the expected laser lifetime. All optical elements are implemented on specially designed aluminium mounts. Shims provide at the same time initial tunability and mechanical stability. The current design does not contain an optical isolator. To avoid perturbation direct back-reflection into the DFB lasers [4], all optical elements are implemented under a slight angle against the optical axis. A partially representative prototype has been validated through a clock stability measurement [3].

Fig. 2.

Functional implementation of the Laser & Optics sub-system, with the components 1 Laser Diode, 2 waveplate, 3 polarizing beamsplitter, 4 beam absorber, 5 beam circularization, 6-8 beamsplitter, 9 photodetector for optical power detection.

The Laser Diode Sources

During the former development phase of the industrial, optically pumped Cs clock, the laser diode has been evaluated as the most critical technology. The reach of optimal linewidhts below 1 MHz [6] was historically linked to the use of external cavity diode lasers. Although this technology is well known, it appears to add a significant amount of complexity to a commercial clock.

For Cs clock application and in the frame of the European Euripides LAMA project, III-V Lab has recently developed an active region Al-free DFB laser diode emitting at Cs D1 line 894nm [6]. The implementation is based on previous results at Cs D2 line 852nm. The laser is a Separate Confinement Heterostructure (SCH). The cavity single transverse mode behavior is enabled by a narrow width ridge waveguide. On the other side, the single longitudinal mode operation is ensured by a second-order Bragg grating. The lasers show single mode behavior at Cs D1 line. The linewidth lies in the range of 0.7 to 1MHz. Ongoing developments aim at DFB Cs D1 line at ambient chip temperature.

In parallel, the eagleyard Photonics is currently running the manufacturing of a lot of DFB lasers at 894nm [7]. The thermal/electro-optical tuning coefficients and output power are expected to be nearly identical for the two sources. In summary, today even two European suppliers provide suitable TO3 packaged DFB laser sources as a commercial product. Addressing the Cs D2 transition at 852nm, comparable clock performance was observed for both laser diode sources [3].

A.

LASER DIODE

The design baseline is a TO3 packaged DFB laser diode as an off-the-shelf component with modifications. Liftetime and component construction have been identified as most critical issues. They will be evaluated in detail in the current project phase. In contrast and based on return on experience from former laser diode qualifications, radiation induced damage (100krad over 12years) was evaluated to be a minor risk. The same holds for the hermeticity of the TO3 packaging which benefits from longstanding industrial heritage. The Thales supplier evaluation concerning industrial quality management and technical feasibility in 2016 was positive for the two supplier eagleyard Photonics and III-V Lab.

B.

PHOTODIODE

Former CNES evaluations demonstrated that the off-the-shelf detector initially used for the OSCC development cannot be space qualified mostly due to hermeticity issues of the packaging.

In early 2016 TED conceived with First Sensor a customized detector for a space evaluation. It is based on an off-the-shelf large-area photodetector and a customized TO-packaging. The former is similar to a quadrant detector currently qualified for the use in a space sun-sensor application. Compared to the S1337, it is expected to even slightly increase the detected clock signal level (clock stability) due to a larger active area.

Fig. 3.

View of a similar packaging of the large area photodetector (active area 11 mm diameter).

The photodetector sensitivity and dark noise level are of key importance for clock performance. Concerning space application, a loss of photosensitivity and an increase of dark noise is expected due to (radiation induced) displacement damage. The two aspects will be verified in the space-evaluation program 2016-2017. The irradiated samples can also be used to model the expected (thermal) annihilation of loss of photosensitivity. Indeed, the total mission dose is typically applied over a very short time, ignoring the continuous annihilation effects all along the mission. A dedicated test will also address the possible impact of substrate type (n-type or p-type) to radiation sensitivity.

The customized TO packaging will benefit from supplier heritage on a similar packaging for EUCLID mission. The Thales supplier evaluation of First Sensor concerning industrial quality management and technical feasibility in 2016 was positive.