Adaptive Optics for Extremely Large Telescopes (1808.02693v2)

Abstract: Adaptive Optics has become a key technology for the largest ground-based telescopes currently under or close to begin of construction. Adaptive optics is an indispensable component and has basically only one task, that is to operate the telescope at its maximum angular resolution, without optical degradations resulting from atmospheric seeing. Based on three decades of experience using adaptive optics usually as an add-on component, all extremely large telescopes and their instrumentation are designed for diffraction limited observations from the very beginning. This review illuminates the various approaches of the Extremely Large Telescope, the Giant Magellan Telescope, and the Thirty-Meter Telescope, to fully integrate adaptive optics in their designs. The article concludes with a brief look into the requirements that high-contrast imaging poses on adaptive optics.

Overview of Adaptive Optics for Extremely Large Telescopes

The paper presented in "Adaptive Optics for Extremely Large Telescopes" by Stefan Hippler, published in the Journal of Astronomical Instrumentation, explores the crucial role adaptive optics (AO) play in optimizing the performance of the current and forthcoming extremely large telescopes (ELTs). These include the European Extremely Large Telescope (ELT), the Giant Magellan Telescope (GMT), and the Thirty Meter Telescope (TMT). The primary aim of AO is to alleviate optical distortions caused by atmospheric turbulence, thereby allowing telescopes to achieve their maximum angular resolution.

The inception of adaptive optics in astronomy dates back to Horace W. Babcock's pioneering work in 1953. The implementation involves a fast real-time controller (RTC) creating a closed-loop system between a wavefront sensor (WFS) and a wavefront corrector, often a deformable mirror (DM). The integration of AO with ELTs is a fundamental aspect of their design from inception, reflecting their commitment to achieving diffraction-limited observations.

Technological Developments and Historical Context

The effectiveness of AO systems has evolved significantly over the past few decades. Initial AO systems in the late 1980s and 1990s were augmentations to existing telescopes, while AO today is an intrinsic component of telescope design. The first major leap in AO implementation occurred with the Keck II telescope, documented by Wizinowich et al. in 2000, which introduced AO systems in 8–10m class telescopes. The introduction of laser guide stars (LGS) marked a significant milestone, enhancing the operational capability of AO systems, especially in observing faint astronomical bodies.

Subsequent advancements have been realized with systems like MAD and GeMS, expanding the corrected field of view and sky coverage through multi-conjugate adaptive optics (MCAO) and ground-layer adaptive optics (GLAO). These advancements have been critical as they enable a more uniform correction across larger fields of view, a necessity for the upcoming ELTs.

Contributions of ELTs and Their AO Systems

Each of the current and near-future ELTs has incorporated adaptive optics in unique ways. The ELT features a five-mirror optical design with a large adaptive quaternary mirror equipped with 5,316 actuators for real-time AO corrections. In contrast, the GMT uses an adaptive secondary mirror with a similar actuator density, enhancing its observational capabilities significantly. The TMT, differing architecturally, depends on a facility AO system named NFIRAOS, which integrates advanced DMs to handle complex correction tasks, although it lacks an adaptive secondary mirror in its initial design.

Implications and Future Directions

The implications of successfully implementing AO in ELTs are profound. AO systems enable these telescopes to explore diverse astronomical phenomena ranging from exoplanet characterization to deep-field imaging of high-redshift galaxies, bridging gaps in our current astronomical knowledge.

As future developments unfold, there is considerable anticipation surrounding the enhancements in high-contrast imaging capabilities, critical for observing exoplanets and other faint celestial phenomena. Instruments like METIS on the ELT are expected to deliver unprecedented contrast and resolution, thereby paving the way for future exploration of Earth-like planets and potentially habitable zones.

Furthermore, the research suggests a continued focus on reducing non-common path aberrations and implementing advanced coronagraphy techniques. These developments aim to augment the contrast achievable through existing AO systems.

Conclusion

In summary, the integration and advancement of adaptive optics within extremely large telescopes represent a pivotal progression in observational astronomy. The research by Stefan Hippler provides a comprehensive overview of the technological advancements and challenges faced in this domain, underscoring the transformative potential of AO systems in facilitating astronomical discoveries with unparalleled clarity and accuracy. As the technological landscape evolves, these systems will undoubtedly remain at the forefront of astronomical exploration.