Space

Adaptive optics lifts Earth's atmospheric veil to reveal a sharper cosmos

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Images showing Neptune captured using the new adaptive optics mode, and another with it switched off
ESO/P. Weilbacher (AIP)
Image of Neptune captured by the VLT using  the Narrow-field adaptive optics mode of the MUSE/GALACSI instement
ESO/P. Weilbacher (AIP)
Images showing Neptune captured using the new adaptive optics mode, and another with it switched off
ESO/P. Weilbacher (AIP)
Shot of Neptune taken by the VLT using the new adaptive optics mode (left) and a comparable image taken earlier by the Hubble Space Telescope
ESO/P. Weilbacher (AIP)/NASA, ESA, and M.H. Wong and J. Tollefson (UC Berkeley)
Images showing globular star cluster NGC 6388 shown on the left without adaptive optics with MUSE in its wide-field mode, and on the right with adaptive optics in the narrow-field mode – the center image highlights the difference in clarity
ESO/S. Kammann (LJMU)
View gallery - 4 images

Astronomers at the Paranal Observatory in Chile have achieved first light with a cutting-edge adaptive optics mode for the European Southern Observatory's (ESO) Very Large Telescope (VLT), designed to remove interference caused by Earth's atmosphere. The ESO has released some of the first images captured following the upgrade, and impressively, they appear even sharper than comparable shots taken by the Hubble Space Telescope.

One of the greatest problems faced by conventional ground-based telescopes is the disturbance caused by the particles that populate our planet's dense atmosphere, which disrupt and scatter the light emitted by distant bodies such as planets and massive galaxies. This turbulent effect, known as astronomical seeing, is the reason that stars seem to twinkle in the night sky.

Scientists and engineers are able to mitigate some of the disruptive mixing of Earth's atmosphere with the help of advanced instrumentation and software, known collectively as adaptive optics.

The ESO has just released the first images taken using the new mode of its Ground Atmospheric Layer Adaptive Corrector for Spectroscopic Imaging (GALACSI) adaptive optics module. GALACSI, which works in conjunction with the Multi-unit Spectroscopic Explorer (MUSE) instrument, is mounted on the fourth unit of the VLT, known as YEPUN.

Shot of Neptune taken by the VLT using the new adaptive optics mode (left) and a comparable image taken earlier by the Hubble Space Telescope
ESO/P. Weilbacher (AIP)/NASA, ESA, and M.H. Wong and J. Tollefson (UC Berkeley)

GALACSI had previously been able to work with the MUSE spectrograph to obtain wide field-of-view observations of the cosmos that were relatively free from atmospheric interference. The new mode, which makes use of a technique called laser tomography, allows GALACSI to work with MUSE in its Narrow-Field setting, in which it can capture a more detailed image of a smaller patch of sky. The narrow-field mode is much better suited to capture sharp images of planets, black holes, or any other of a host of celestial objects than the wide-field equivalent.

Here's how it works – four 30 cm (12 inch)-wide, 22-watt laser beams are projected into the sky above the Paranal Observatory, stimulating sodium atoms high in the atmosphere, which essentially act like persistent artificial stars, revealing turbulence at varying altitudes. GALACSI observes disturbances in the light, and calculates corrections roughly one thousand times per second. These corrections are used to constantly manipulate the shape of the VLT unit's flexible secondary mirror, which rests on a mount holding 1,170 actuators.

Images showing globular star cluster NGC 6388 shown on the left without adaptive optics with MUSE in its wide-field mode, and on the right with adaptive optics in the narrow-field mode – the center image highlights the difference in clarity
ESO/S. Kammann (LJMU)

By shifting the mirror to account for disturbances in the atmosphere as they occur, the telescope is able to capture images significantly sharper than those taken by the Hubble Space Telescope at visible wavelengths. The images captured in the first light observations include a shot of Neptune, a globular star cluster and other cosmic objects.

Astronomers will now be able to observe the properties of our solar system, and the vast cosmos beyond from Earth with unprecedented clarity. The results of the new observations will be used to inform the design and construction of the future European Extremely Large Telescope (E-ELT). Once completed, the E-ELT will play host to a 39-meter (128-ft) main mirror, making it the largest optical/near-infrared telescope in the world.

Scroll down to see an ESO video zooming in on globular star cluster NGC 6388, switching between the wide-field and narrow-field MUSE modes, the latter of which has adaptive optics turned on.

Source: ESO

View gallery - 4 images
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