Astronomers use old-time math to measure distance, age of one of the oldest objects in the universe - Action News
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Science

Astronomers use old-time math to measure distance, age of one of the oldest objects in the universe

They are some of the most spectacular sights in the sky: globular clusters, tight collections of hundreds of thousands or even millions of stars. Now, using trigonometry, astronomers have accurately measured the distance to one of the oldest in our universe.

Canadian researcher says it's 'all part of the origin of things'

This ancient stellar jewellery box, a globular cluster called NGC 6397, glitters with the light from hundreds of thousands of stars. The new measurement sets the cluster's distance at 7,800 light-years away, with just a three per cent margin of error. NGC 6397 is one of the closest globular clusters to Earth. (T. Brown, S. Casertano/STSCI/NASA/ESA)

They are some of the most spectacular sights in the sky: globular clusters, tight collections of hundreds of thousands or even millions of stars. Now, using the Hubble Space Telescope and ancient math astronomers have accurately measured the distance to one of the oldest ones in our universe.

Until now, astronomers have used the brightness, or luminosity, of stars to calculate the age of globular clusters. But this method has produced readings that are inaccurate by10 to 20 per cent. That's enough to make some estimates come in older than the universe itself.

Calculating these distances is crucial toour understanding not only of howthe universe formedbut of how we got here ourselves.

"All this can fold into how the galaxy formed," DonVandenBerg, co-author of the new study published in The AstrophysicalJournal Lettersand professor at the University of Victoria,told CBCNews. "It's all part of the origin of things."

Researchers looked at globular cluster NGC 6397 within our galaxy and used a novel method to calculate its distance, employingmath as old as science itself: trigonometry.

A simple way of understanding this method is to hold your index finger out in front of you at arm's length. Close your right eye and note the position of your finger against a background. Open it and then do the same with your left eye. You will notice that your finger seems to move against the background, though in realityit didn't move at all. This is called parallax.

Every six months, over a period oftwo years, as Earth orbited the sun, the team of astronomers used the Hubble Space Telescope to study this apparent shift of NGC 6397. Capturing the stars as they moved across the telescope's view, they measured the distance of 40 stars within the globular cluster to be about 7,800 light-years away, with just a three per cent margin of error far better than the previous margin of 10 to 20 per cent.

The shifts, or wobbles, of the stars were only 1/100th of a pixel on the telescope's camera and were measured to a precision of 1/3,000th of a pixel.

"This is like standing on Earth and measuring the size of a car tire on the moon to within one-inch accuracy," Tom Brown an astrophysicist at the Space Telescope Science Instituteand lead author of the paper, told CBC News.

You get a sense of just how distant the cluster is in the video below.

And, amazingly, the astronomers calculated that this particular globular cluster was ancient: 13.4 billion years old, to be precise. Looking at it, we see it as an infant in a galaxy that is roughly 13.8 billion years old.

Jewels in the cosmos

Globular clusters are found in halos around galaxies. The stars within them are gravitationally bound and look like a fuzzy ball of light in small telescopes. But in powerful telescopes you can see thousands upon thousands of individual stars, believed to be created at the early stages of the universe's formation.

Since they're so old, astronomers have been seeking to use them to better measure the distance to other objects as well as understand their evolution.

The globular cluster Omega Centauri, with as many as 10 million stars, is seen in all its splendour in this image captured from the La Silla Observatory in Peru. The image shows only the central part of the cluster. (European Southern Observatory)

Astronomers had been using open clusters stars that were formed from the same cloud of gas and dust and that are loosely held together by gravity to measure distances. But these younger, closer stars didn't provide much accuracy.

This new research changes all that.

"This helps give the foundation to models that are used in many parts of astronomy not just looking at starsbut also looking at distant galaxies," Brown said. "And this particular cluster is the anchor in one of the most widely used models in astronomy for interpreting distant galaxies."

The research team hopes to further refine the accuracy of the measurement of the distance to NGC 6397 to within one per cent when the European Space Agency's Gaia space telescope releases its second round of collected data, scheduled for later this month.