Tartu Observatory lies a good two-hour train ride southeast of Tallinn in the former Soviet republic of Estonia. Surrounded by rolling pastureland, the observatory was once a top-secret installation for the Soviet space program, a hotbed of activity for the design of instruments for Soviet-era satellites dating back to the Sputnik program.

In the last 30 years, however, the observatory has fully blossomed in its freedom to pursue astronomy in concert with its western partners. To that end, I recently sat down with Elmo Tempel, an astronomer at the University of Tartu and a member of the European Southern Observatory’s (ESO) 4MOST science consortium.

4MOST (4-metre Multi-Object Spectroscopic Telescope) is a 10-million-euro instrument due to be installed on ESO’s 4.2-meter VISTA telescope in Chile. Over five years, it will survey some 50 million targets, covering almost the entire southern sky.

And although the observatory’s role 4MOST is modest, Tempel’s work in developing the algorithms needed to maximize the instrument’s celestial targeting is crucial to the survey’s success.

Spectroscopy is astronomy’s unsung underdog. For their sheer beauty, visual images of stars and galaxies routinely steal the headlines. But it’s the spectroscopic analysis (the breakdown of a given celestial target’s light into its electromagnetic spectra) that enables astronomers to identify the chemical composition of stellar atmospheres and galaxies.

4MOST’s Surveys Are Expected To Begin Late Next Year

4MOST should provide the kind of robust statistical data needed to make conclusions about how our own Milky Way evolved, Tempel told me during an interview in his observatory office.

4MOST will observe tens of millions of targets, which will allow it to address many science questions statistically, says Tempel.

Even though the instruments will, is, will do surveys that cover the gamut of our cosmos, Tempel is most interested in surveys of our own galaxy.

Why This Survey Is Important For Understanding Our Milky Way Galaxy

4MOST Milky Way surveys are designed to help us understand the Milky Way and how it evolved to its present-day configuration.

The European Space Agency’s (ESA) Gaia spacecraft discovered many new ancient stellar streams in the halo of our galaxy, says Tempel. But it did not take spectroscopy, says Tempel. So, 4MOST is designed to follow up on Gaia’s Milky Way observations and take these stars’ chemical fingerprints, he says.

This will give galactic theorists a much better idea of these ancient stars’ past movements through the galaxy, says Tempel. This will enable us to deduce more about the merger history that actually formed the Milky Way that we see today, he says.

What’s Unique About 4MOST?

We’ll be able to survey more than 2400 objects simultaneously, says Tempel. One single observation covers 4.2 square degrees in the sky, he says. The celestial objects are known and selected from previous imaging surveys, says Tempel.

The instrument will use 2436 optical fibers to simultaneously capture incoming light from the celestial targets. In other words, each optical science fiber will capture light from a separate science target and funnel it into the 4MOST instrument all at the same time.

Tempel is working on two algorithms that will help enable 4MOST to make the most efficient use of its observing time. One involves developing an algorithm to carry out the survey in an automated way so that human interaction isn’t needed to select targets, he says.

Every time we point the telescope, there are usually more targets available than we can observe simultaneously, he says. So, for each fiber, an algorithm is used to decide which target to select for a given observation, says Tempel. Then within a certain physical range on the instrument’s focal plane, each fiber can be moved to the celestial target you want to observe, says Tempel.

How can the 4MOST team be sure that the instrument is observing the correct celestial target?

Because we can move the fibers to an accuracy of micrometers, says Tempel.

4MOST Will Probe Deep Into The Milky Way

The 4MOST instrument will study the formation history of the Milky Way, and the earliest phases of its chemical enrichment encoded in the orbits, chemistry and ages of its stars, says ESO. In the process, its survey samples will be of unprecedented size out to larger distances and greater precision than conceivable with any other on-going or planned survey, notes ESO.

For his part Tempel is both interested in the history of our Milky Way as well as how it fits in with the rest of the cosmic web.

4MOST will provide a dense and deep map of the stellar properties in the Milky Way as well as some of the largest of the Milky Way’s satellite galaxies, says Tempel.

We don’t have any direct observations telling us how the Milky Way came together, says Tempel. So, the aim is to observe the oldest and most metal poor stars in our Milky Way which will give us information on how the galaxy’s formation began, he says.