The Young Astronomers
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It has certainly been a long while since Hannah and myself produced a podcast episode though we hope to bring you a few episodes over the next couple of weeks.
To kick us back off, here is the next section of our interview with Professor Bill Keel. In this segment we take a look at Voorwerpjes along with Hanny’s Voorwerp.
Hannah and I will also be returning to these topics in more detail in our next Podcast.
The Star Sailor Podcast: Episode 4 Part One – Voorwerpjes & the Voorwerp
After a long break we have our next instalment,
Part One
Part Two
More information and transcript is pending.
We hope you will enjoy!
After many delays the long awaited second part of our interview with Dr. Robert Simpson.
A transcript is being produced and will be uploaded shortly.
Before I go, If you have any questions for Hannah or myself you can get them too us via our emails or via our new formspring accounts: -
Hannah’s - http://www.formspring.me/Stellar190
Peter’s - http://www.formspring.me/Lightbulb500
Until next time 
As promised (if slightly delayed), here is the ‘video’ version of our recent contribution to 365 Days of Astronomy.
Hannah and I would like to thank both Dr. Robert Simpson for his time, and 365 for the opportunity to get the Star Sailor podcast out to more people.
As indicated by the title a rather large section (actually the majority), of the podcast is yet unreleased due to time constraints on 365 podcasts. rest assured however that the remaining 12 minutes of the interview will be released soon, hopefully before the end of the year 
Thanks for listening and reading.
365 Days of Astronomy - http://365daysofastronomy.org/
SDSS Image: – Credit SDSS
ESO Images: – Credit ESO
Edit: – Now with Transcript
Transcript:
[Peter] Hello and welcome to the 365 Days of Astronomy Star Sailor podcast ‘Questions of a Stellar Nature’ with Peter Clark, Hannah Hutchins and Doctor Robert Simpson of the University of Oxford. Hello and welcome!
[Robert] Hi, thanks!
[Peter] We’re just going to get stuck right in with the questions, so Hannah:
[Hannah] So what’s your favourite area in astrophysics and why?
[Robert] I ought to say that my favourite area of astrophysics is the one I studied in or schooled in if you like, so I ought to say it’s star formation but it is and it isn’t. I mean for most of us we fall into these things because we like them, and originally I was really into astrophysics because of things like Star Trek and I always thought time travel was cool (and I still do), and I always read papers about worm holes even though I shouldn’t. And so really star formation is the one I know the most about and it’s a very important and interesting area of astrophysics, but I also love cosmology for answering the really big questions, and I love the kind of really fringe stuff like time travel and worm holes because it really delves into areas that science fiction only dares touch. And of course I think like a lot of other people I love planets so solar system astronomy and astrophysics, and those beautiful pictures of the planets, the moons and understanding how we all formed and all these landscapes around us as well as the universe itself. There’s probably a lot I like about astrophysics so I should stop rambling and let you ask me the more important questions, but I like a lot about astrophysics so that would be the short answer.
[Peter] I am sure everyone listening would whole heartedly agree with you, so moving on to the main topic of the podcast and that’s stars:
Recently the ESO discovered what can only be described as a monster star located within the Tarantula Nebula. R136a1 has been measured to weigh in at a little under 300 solar masses with an estimated birth mass of 320 solar masses, which is more than twice the accepted mass limit of a star (150 solar masses). Anything more than 150 solar masses was expected to be unable to reach hydrostatic equilibrium and blow itself apart as it would be unable to balance its outward radiation pressure with its gravity, and so exceed its Eddington luminosity. Have we discovered something that’s a freak event or are we starting to get below the surface of how high mass stars work?
[Robert] Well we certainly haven’t really scratched the surface on massive star formation; this is a big problem area in lots of ways. The problem is that they’re not very common, and the reason we thought the largest stars would be about 150 solar masses was simply based on looking and going out there looking at big clusters of stars, and this was a paper back in the early part of the last decade basically empirically saying we can’t see stars that are bigger than 150 solar masses. And in fact we couldn’t see them at the time – it was measured to be 120. Up from there we thought well let’s say it’s 150 then. It’s not the most concrete number. The Eddington limit which you mentioned is to do with so for any given star it would have an Eddington limit, so the biggest stars themselves would have very large eddington limits, but the eddington limit (or eddington luminosity ) refers to the radiation that would be required to equal the gravitational energy of a star, so a very very big star would have a very very big eddington luminosity and even the most massive stars we’ve seen seem to be only approaching a 50 percent eddington luminosity if you like, meaning that the radiation pressure pouring out from those stars is only about half the gravitational energy, so there’s still a way to go in terms of their radiation, so perhaps they could get bigger.
This 300 solar mass star certainly does seem to be that big so what it does is it blows out the water, as you say, the 150 solar mass limit, but that limit being based on observation anyway so now we have a new upper limit. There are people that suggest that it was a binary system and we can’t resolve them as independent masses so therefore you’d have two 150 solar mass stars, but that seems unlikely based on measurements of the Doppler shift. If there really where two 150 solar mass stars orbiting each other we ought to be able to detect that in their spectra. But the measurement is pretty robust and certainly the way the technique for making that measurement stands up to the test of other measures of mass that we have, and so it really does look like the 150 solar limit is done and we may be moving on to 300 for now until of course we find the next one because theoretically people have put forward models that suggest we can have anything up to 400 – 450 solar masses.
[Peter] Wow!
[Robert] Yeah, we could have really big stars but of course the rarer they get the harder it is to spot them, certainly spot them nearby, which is where we’d need to see them to measure all this stuff, so it’s a tricky business and hopefully we’ll be finding them because the new technology we have and infrared data we now have lets us do a few things we couldn’t do before and one of those is looking at massive star formation in a great new way.
[Hannah] There’s a proto star that’s been discovered called IRAS134816124 that is still surrounded by the cloud that it formed from. And it’s been confirmed to weigh in at 20 solar masses, and this is particularly interesting as it goes a good way to showing that massive stars form via accretion rather than stellar mergers. Do you now think that we have discovered the secrets to massive star formation or could a spanner be thrown into the works?
[Robert] Yeah, this relates a lot to the last problem which is that these very massive stars are hard to come by because there aren’t as many of them. And infrared measurements that we have from the Very Large Telescope from ESO and a couple of other instruments that are out there at the moment and coming along soon, they all mean that we can look at these things in better detail than we could before and that’s because these things are often embedded within big dusty nebulae and molecular clouds and that makes them hard to see with conventional telescopes that we’ve had up till now.
This very very big one with the accretion disk as you say is notable because it’s the first time we’ve been able to say absolutely that this massive star, this very large star, I think it’s 20 solar masses, that it’s got an accretion disk around it. Now the problem was it was thought that with the lower mass stars it was easy to have accretion; material can fall onto the star through gravity and sort of swirl on and angular momentum gets delivered. But with the really big ones the radiation pressure, the energy pouring out through these new stars, ought to be powerful enough to stop things accreting onto the star. So we need to come up with ways to model that to show that it might be possible, and this observation in the near infrared it’s an Interferometric observation, meaning it’s using more than one dish and putting them together to create an even better picture, this shows that it’s definitely possible because it’s happening. And this is great for science when things like this happen because it’s always good to just totally challenge the conventional thinking which had been that perhaps large stars form by other stars coalescing together. The problem with that though anyway was I don’t think I was ever terribly comfortable with that idea, I mean if you look at the 300 solar mass one we mentioned earlier how many 100 solar mass stars that we see around could have formed to make that one? So it only works for stars that are medium sized, once you get really big you still need a way to create these things.
[Hannah] So have we now discovered the secrets of high mass star formation?
[Robert] Oh no absolutely not! I don’t think we’ve discovered the secrets of massive star formation at all, I think what’s great is to uncover a new piece of evidence that gives us a new line in enquiry so ok massive stars clearly can form through accretion; lets figure out how that works. And is that how they all form? Don’t know! But certainly that’s certainly how some of them form because we can see one. So yeah, spanner in the works? Definitely! More spanners in the works? Why not! That’s what science is all about right?
[Peter] Thank you for listening to the 365 Days of Astronomy Star Sailor podcast ‘Questions of a Stellar Nature’ with Peter Clark, Hannah Hutchins and Doctor Robert Simpson of Oxford University. Thank you!
Until next time
In our first podcast we take a look at the latest version of Galaxy Zoo: – Hubble Zoo.
Peter: Hello and welcome to the first Star Sailor podcast with Peter Clark and Hannah Hutchins. Today we’re discussing the latest reincarnation of Galaxy Zoo: Hubble Zoo!
Hannah: So Hubble Zoo is a citizen science project that uses the general public to classify a whole host of Hubble galaxies, focusing on their morphology.
Peter: For those of you who aren’t well versed in astronomical terms, morphology literally means the shape of a galaxy. The previous Galaxy Zoo’s discovered some very interesting trends between the morphology of any particular galaxy and its location and its distance from the earth, also known as its redshift. Hubble Zoo is designed to take this analysis to the next level and provide an even more detailed analysis of lots of galaxies so its conclusions can be drawn over a wide data set.
Hannah: So the previous galaxy zoo projects 1 and 2 used data from the Sloan Digital Sky Survey data base -
Peter: Thankfully we can shorten this to SDSS, which makes it much easier on us for the podcast.
Hannah: So the SDSS data base mostly has galaxies of relatively low redshift so the galaxies are lurking mainly millions of light years away.
Peter: We should add now that redshift isn’t a direct measurement of distance; it’s actually a measure of how the light from a particular galaxy has shifted to one end of the spectrum. This can either be blue or red. As most galaxies are moving away from us, the light is stretched into longer wavelengths, meaning they are red shifted. The more the light has been redshifted the further away the galaxy is, so it allows you to calculate a rough estimate of distance.
Hannah: The opposite of redshift is blueshift, which means that the light of the galaxy will be shifted to the bluer end of the spectrum, as it’s moving towards us.
Peter: This happens because the light is essentially compresses into shorter wavelengths, so appears bluer. The most famous example of a blue shifting galaxy is the nearest large galaxy to the Milky Way, the Andromeda, or M31. It is in fact in a projected collision course with the milkyway and should collide with us within the next few billion years. Don’t worry; it’s not something you should be worried about!
Hannah: The Sloan telescopes aperture –
Peter: Which is a very fancy word for a mirror –
Hannah: – Is 2.5 metres, whereas the Hubble telescopes aperture is 2.4m.
Peter: Generally speaking the larger the mirror you have on a telescope the better images it can produce, despite this, Hubble sits above the Earth’s atmosphere and so despite it having a smaller aperture it can take much better photos as I’m sure you’ve all seen in the Hubble press releases.
Hannah: So because the Hubble telescope is outside of the Earth’s atmosphere it can further back in the universes history, as much as billions of years.
Peter: This means that galaxy zoo is now able to study galaxies as they were forming, rather than long after the formation process was complete. This is allowing galaxy zoo to put together an idea of how galaxies in general form and how the formation process between say an elliptical and a spiral differ.
Galaxy zoo has already discovered many interesting objects, as well as a completely new type of galaxy known as the Peas.
Hannah: The Peas are highly compact galaxies which are star forming at incredible rates.
Peter: This rate is many times that of what is currently occurring in the Milky Way.
Hannah: The Milky Way churns out one to four stars a year whereas the Peas can churn out up to 40 sun-like stars a year.
An example of a Pea; Credit: SDSS
Peter: As you may have guessed from their name, the Peas on the SDSS appear to be green, small and round, and well, pea like; hence their name. They where first identified as a bit of a joke on the forum but what turned out from one or two turned into an entire collection that become impossible for professional astronomers to ignore.
Hannah: Followed inevitably by loads of puns about garden peas –
Peter: And well, give Peas a chance…
Hannah: Yes
Peter: Which you can still find on the forum!
Whilst the peas are incredibly interesting objects they are by no means the only objects discovered by Galaxy Zoo that are completely out of the ordinary. One of the most famous is of course Hanny’s Voorwerp. The Voorwerp lies just outside the galaxy IC 2497 – yes astronomers are really inventive with naming things. The voorwerp is believed to be a free floating cloud of ionized oxygen without any sign of star formation at all.
Credit: William Keel, Anna Manning, 3.5m WIYN Telescope
Currently the most popular theory for what causes the ionization of the gas in the first place is a residual light echo from IC 2497’s once active nucleus which has since become inactive and so we’re seeing the residual trace in the gas of the voorwerp.
It is also believed that eventually the Voorwerp will fade from view as it loses the rest of its energy and just becomes one other boring cloud of hydrogen (Edit: -As Alice pointed out it also contains helium and oxygen and other elements with the oxygen being ionised) gas sitting in space.
The discovery of the voorwerp sparked a hunt within the zoo for any other ionized gas clouds found within the SDSS data base. No other Voorwerps where discovered however an interesting class of galaxies where discovered in the process.
Hannah: The Voorwerpjes. Though we’re not actually quite sure how you pronounce that so we just call them floor pies…
Peter: It is Dutch for ‘small objects’ incase you’re interested.
Hannah: These galaxies have massive clouds of ionized oxygen, hydrogen, thousands upon thousands of light years wide. These clouds of ionized gas are ionized by the super massive black hole at the centre of these galaxies, material is falling into the black hole in a doughnut shaped accretion disk, and as the material speeds up around the black hole like water going down a plug hole it releases a heck of a lot of energy, such as ultraviolet and x-rays.
So as the radiation is emitted by the centre of the galaxy the radiation then strips the hydrogen or oxygen clouds of their electrons, therefore ionizing the gas and lighting it up.
So as you look at the SDSS images you can see massive pink or blue clouds stretching across the galaxies for up to ninety thousand light years.
From left to right: Mkn 266, 2MASX J14302986+1339117 and UGC 7342. Image credit: SDSS
Peter: They really are very interesting object to look at! To save you from having to hoak through the Sloan data base we’ve picked out the some of our favourite voorwerpjes and put them in the slide show.
To finish up with we’d like to invite you all to come and join us at galaxy zoo, you can help contribute to citizen science and make a real impact on astronomy as a whole.
The website is completely free to sign up for it and it’s incredibly fun. If you’d like to join us it’s at www.galaxyzoo.org, if you need a link directly to the site you can find it in the description if you’re listening to this off of Youtube and the post below if you’re reading this off The Witty Astronomers blog.
Galaxy Zoo is also famed for its forum, with its incredibly friendly place that like minded people can talk about everything from the galaxies they are classifying, their favourite taste in music, coffee…
Hannah: Socks…
Peter: chocolate
Hannah: Elephants
Peter: Gardens… You never know!
Hannah: Marshmallows…
Peter: It’s a rather diverse place! So if you want to come and join us we’ll be delighted to have you at www.galaxyzooforum.org, again that’s in the description or in the post below.
We hope you’ve enjoyed listening to the first Star Sailor podcast and we hope to do this reasonably regularly, again we hope we haven’t been too boring for you but thank you for listening!
The SDSS home page can be found at http://www.sdss.org/
Hubble Zoo can be found at www.galaxyzoo.org
The Galaxy Zoo forum can be found at www.galaxyzooforum.org
AAPOD
Portal to the Universe
