Andrew Pontzen, UCL
The University of Oxford have announced their role i the European Extremely Large Telescope and it's going to be big. Andrew Pontzen from the University College London gave an update to Kat Arney...
Andrew - Itís slated to be ready and take its first observations in 2024 so itís still some way off. But the thing about this telescope is itís going to be almost 40 meters across. So, itís a 40-meter digital camera if you like, to look at the night sky. Just to give you some sense of just how big that is, itís going to be assembled out of lots of sort of small mirrors that focus the light. 800 of these small mirrors and each of those 800 small mirrors is sort of the size of a person. So, you assemble all of those together and you have this huge collecting area to collect light coming at you from space. It means weíre going to be able to see extremely faint objects and get a lot more detail than we could before. The news thatís come this week is that the latest instrument thatís going to sit on the end of this camera and actually take the observations, take all that light and turn them into something we can use has just been commissioned. Itís just been signed off Ė something called the HARMONI spectrograph and itís really going to put that huge collecting area for light to best use because itís not just going to take pictures. Itís not like a digital camera that just takes some coloured pictures.
Kat - I'm assuming itís better than an iPhone or similar for camera phone.
Andrew - Even better than an iPhone.
Kat - Other camera phones are available.
Andrew - Your camera images are made out of individual pixels, individual dots which are coloured. Every single one of those, itís going to take what we call a spectrum. Itís basically going to break the light down into all of the different wavelengths or colours that you can possibly separate it out into.
Kat - Is that across the whole of the electromagnetic spectrum or still just a kind of a chunk of that?
Andrew - Well, itís the chunk of that because itís going to be built in Chile which is quite high up, but there's still atmosphere that the light has to come through. That means a lot of it is filtered out. So, itís just the chunk that you can actually get at which is the visible light that you and I can see, plus some infrared light. But itís going to break it down into that spectrum and that means every single dot of say, galaxy that youíve taken a picture of, you're going to get detailed exquisite information about everything thatís going on in that tiny little dot.
Kat - So, weíre going to get some really awesome pictures. Is it that kind of telescope? Weíre going to see these amazing things.
Andrew - You certainly are going to see incredible images, but you'll also going to be able to boil it down into data. Thatís what we really care about in astronomy now, itís data. And so, for example, in one shot, you could get a beautiful image of a galaxy but you could also tell exactly how that galaxy is rotating. In the past, thatís something that weíve needed to do with separate instruments. You would need to take one picture to have a look at what it looks like and then apply a completely different instrument to get a spectrum. So now, you can do all of it at once, get all of this very faint light, collect it altogether, and itís just going to be so exciting. But it is nine years away.
Kat - And is it the biggest telescope? Is it going to be the biggest in the world?
Andrew - It certainly is. The Americans are trying to compete but they're not quite going to get there because they're building a 30-meter telescope. This one will be very nearly 40 meters across.