Little Stars ♥

According to the laws of physics, a planet in the shape of a doughnut (toroid) could exist Physicists say that such a planet would have very short nights and days, and arid outer equator, twilight polar regions, moons in strange orbits and regions with different gravity and seasons.

‘SHARKs’ WILL HELP LARGE BINOCULAR TELESCOPE HUNT FOR EXOPLANETS

** Synopsis: Two new instruments will give the Large Binocular Telescope a set of sharper eyes capable of studying planets outside our solar system in greater detail. **

A pair of new-generation instruments to be mounted on the world’s largest optical telescope, the Large Binocular Telescope, or LBT, located on top of Mount Graham in Arizona, will turn the telescope into a formidable hunter of extrasolar planets. Named SHARK (short for System for coronagraphy with High order Adaptive optics from R to K band), the instruments will enable astronomers to obtain direct images of exoplanets, including very faint ones, by more effectively blocking the otherwise overpowering light from their host stars.

INAF, the Italian National Institute for Astrophysics, is leading the international consortium that will build the instruments and will also manage their scientific use.

SHARK recently has received the official green light from the LBT board, and the two instruments are expected to become fully operational by the end of 2019. SHARK consists of a pair of instruments working synergistically in visible light (SHARK-VIS) and in the near infrared (SHARK-NIR). These will be operated in parallel, taking advantage of the two big 8.4-meter mirrors of the LBT, thus making it the first telescope in the world capable of observing exoplanets simultaneously over such a wide range of wavelengths.

The main problem exoplanet hunters face when studying exoplanets is the extreme contrast between the planets’ faintness in comparison to their host stars’ light, explains Christian Veillet, director of the Large Binocular Telescope, which is managed by the University of Arizona.

To be able to study candidates for potentially Earth-like planets, for example, astronomers need more sophisticated instruments to tease out the signal from the noise.

The “SHARKs” will take full advantage of the outstanding adaptive optics system mounted on the LBT, which was also developed by INAF. This system corrects in real time the image distortions induced by the atmospheric turbulence to deliver final frames that are characterized by a sharpness and quality of detail better than those obtainable with the Hubble Space Telescope.

“LBT’s adaptive optics is currently undergoing a makeover offering even better performance, which will be fully utilized by SHARK to bring the LBT to the forefront of what is possible in this arena,” Veillet says. “We are preparing the path to doing unprecedented science on the next generation of telescopes, such as the Giant Magellan Telescope, an LBT on steroids with seven 8.4-meter mirrors on the same mount instead of two.”

“With SHARK, we will observe exoplanets at unprecedented angular resolution and contrast, so that we will be able to go closer to their host stars than what has been achieved up to now with direct imaging,” says Valentina D’Orazi of the INAF-Osservatorio Astronomico di Padova, instrument scientist for SHARK-NIR. “This will be possible thanks to the use of coronagraphy, which blocks out the light from the central star and highly improves the contrast in the region around the source, thus allowing us to detect the planetary objects we want to study, which otherwise would remain hidden in the star light.”

“With this great combination, we will finally be able to reveal many exoplanets around stars in our galactic neighborhood and better characterize their properties, by also using images in optical light taken for the first time in the northern hemisphere,” adds Fernando Pedichini of the INAF-Osservatorio Astronomico di Roma and principal investigator of SHARK-VIS.

With SHARK, it will be possible to directly image gaseous giants in the outer regions of exoplanetary systems, thus obtaining pieces of information about the architecture of such systems that are complementary to those provided by techniques purely focused on detection. Such techniques include observing the gravitational tug unseen planets exert on their host star, or the minuscule dip in a star’s brightness when a planet passes in front of it.

“These observations are key to understanding the formation mechanisms of planetary systems,” says Simone Antoniucci of the INAF-Osservatorio Astronomico di Roma, instrument scientist of SHARK-VIS. “Moreover, one of the unique features of SHARK will be the capability to directly observe the formation process of giant planets around very young stars.”

“Thanks to the outstanding sensitivity of the LBT adaptive optics system, SHARK-NIR, used in parallel with SHARK-VIS and the LBTI LMIRCAM instrument, will allow us to study not only exoplanets, but also astrophysical phenomena,” says Jacopo Farinato, astronomer at the INAF-Osservatorio Astronomico di Padova and principal investigator of SHARK-NIR. “For instance, we will be able to study with formidable accuracy disks and jets of young stars, gas envelopes around evolved stars, asteroids and minor bodies of the solar system and even the brightest extragalactic sources such as active galactic nuclei.”

“While these two SHARKs are built as instruments to be operated by the teams who built them, they will be open to the whole LBT community,” Veillet adds. “Both teams have garnered an impressive scientific collaboration, covering the wide range of potential scientific programs as well as the diverse partnership on which LBT is built.”

TOP IMAGE….Each SHARK will be installed on one side of the LBT Interferometer (LBTI), the green structure seen in the middle of the picture between the two main mirrors of LBT.

CENTRE IMAGE….SHARK-NIR

LOWER IMAGE….SHARK-VIS

Jupiter’s Little Red Spot

Columbus laboratory at night

ESA astronaut Alexander Gerst floats inside the International Space Station’s European Columbus laboratory. The image was taken during his first flight in 2014.

The lights in the laboratory are dimmed to a pinkish glow during the crew’s off-duty time. Columbus houses NASA’s Veggie greenhouse, where researchers are growing lettuce in weightlessness. Previous experiments showed that red light is best for growing plants in space.

Veggie is already a favourite experiment for astronauts because it offers fresh food at the end of a harvest. Learning how to grow food in space is essential for longer trips further from Earth.

Nearly a decade ago, the Columbus laboratory set sail to become Europe’s largest single contribution to the International Space Station. Shortly after, the first Automated Transfer Vehicle – the most complex spacecraft ever built in Europe – arrived at the orbital outpost.

There is a lot to celebrate in 2018: the 10th anniversary of the Columbus laboratory and the Automated Transfer Vehicle series, plus Alexander’s second mission to the Space Station.

He will be launched in June on Soyuz MS-09 together with NASA astronaut Jeanette Epps and Russian cosmonaut Sergei Prokopyev. He will fulfil the role of commander during the second part of his six-month.

This is the second time a European astronaut will be commander of the Station – the first was Frank De Winne in 2009.

Credits: ESA/NASA