Sunday, June 30, 2013

Age is relative


My birthday breakfast :D
It is not that I was awoken at quarter to nine that made me wonder if birthdays were scared anymore,
nor the fact that I got a call from my beloved 4-year-old nephew before I had even imagined a steaming hot cup of coffee in my hand, but the fact that if I was on one of the many other worlds out there right now it would not even be my birthday today.

So I thought I would find out how old I would be today on some of the other fantastic planets out there.

Mercury: 100 years and 248 days

Venus: 39 years old almost to the earth day

Earth: 24 years old (party in St Andrews tonight for all those at NAM 2013)

Mars: 12 and ¾ :D I think I will start using my Martian age to describe my mental age from now on.

Jupiter: 2 years and one week

Saturn: 297 days

Uranus: 103 days, this is getting a little silly now.

Neptune: 53 days

Pluto (hey! It was a planet when I was little.): 36 days

Hmmm. What about in another solar system?

Alpha Centauri Bb (the closest exoplanet to our solar system): 2,707 years

51 Pegasi b (the first exoplanet discovered to orbit a sun-like star): 2071 years

or

Kepler-16b (or Tatooine like Luke Skywalker): 38 years old; that is not too bad.

or I know,

55 Cancri e (the diamond planet, they are a girls best friend after all): 12,000 years old, well I think we will give that one a miss.

How about this,

HD 2952b: 21 years old. That is more like it. Now I just need to find a way of getting 115 light years away. Hmm maybe I will stick it out on Earth this year.

Now go eat cake and be merry! 

Thursday, June 13, 2013

Look around you: what do we really know about the Milky Way?


Milky Way, Arizona photo by Jim Richardson
Look around you, just by observing the room you are sitting in or what you can see outside the window could you describe what the building looks like from the outside?

This is the same situation we are in with our own galaxy, the Milky Way. Sitting at the edge of the room looking around us and attempting to work out the structure of the building. 

On a clear night away from the light pollution of civilization you can see the galaxy stretched from east-to-west across the sky, the centre of the galaxy obscured by dense gas and dust.
The Earth and Sun sit on the edge of galactic suburbia in an outer spiral arm called the Orion arm roughly 27,000 light years from the galactic center. All of the stars that you see in the night sky are part of the Milky Way, which contains up to 400 billion stars. 

So what does the Milky Way look like, what is its shape and structure?

Believe it or not we are still not completely sure. The diagrams of the Milky Way that we see are actually based on other galaxies that we can see in the sky.
If you look in the night sky you can actually see some of the galaxies that are part of our local group. Two of our closest neighbors are clearly visible from the southern hemisphere, the Small and Large Magellanic Clouds, are satellites of the Milky Way. These satellites sit at a distance of 197 and 164 thousand light years away with each containing several hundred million stars. These, however, have irregular structures and are around 1/100 times the mass of the Milky Way. The largest member of the local galactic group, M31 the Andromeda galaxy, is a spiral galaxy like the Milky Way. It is the only galaxy visible with the naked eye from the northern hemisphere despite the fact that it is 2.5 million light years away, though it is getting closer and we are predicted to collide with it in 4 billion years.

The local galactic group.
If we look beyond our local group you can see more and more galaxies filling the blank spaces between the stars looking back through both space and time. The famous Hubble deep field images revealed hundreds of billions of galaxies all different shapes and sizes and yet with common trends. All galaxies seem to fall into a number of types, spirals, barred spirals, and elliptical. 

The first HST Deep field from 1996

So where does the Milky Way fit in?

We have looked out the window and seen what the buildings around us look like. Now we need to take a look around the room and determine which one it could be.

The structure of different galaxies.
Despite decades of observations the specific spiral structure of our own galaxy eludes us, with questions spanning from the number of spiral arms to the morphology of the central bulge or bar. The spiral structure of the Milky Way was first determined by observing the distribution of the stars in the sky; however, at distances greater than a few thousand parsecs accurate distances are hard to determine. Instead astronomers measure the distribution of different gasses such as CO and HI, which map out the gaseous emission in the galaxy. This by no means solves all of the problems faced by the previous methods used it is still hard to map the opposite side of the galaxy as well as determining the distance to certain features.


So what astrophysicists are doing is using simulations to generate synthetic maps of galactic emission to determine the structure of our galaxy. These diagrams show the observed velocity of HI emission verses longitude with the simulated emission velocity over-plotted, the corresponding basic line structures simulated for the Milky Way on the left (from C.L. Dobbs et al. 2012).
On the left-hand side are possible Galactic features, a two-armed spiral pattern (top), a four-armed spiral pattern (centre) and three rings of different radii (bottom), with the position of the observer marked by the grey cross. On the right-hand side panels is the location of the spiral arms in a velocity–longitude plot from observations of our galaxy and the velocity-longitude structure of the left spiral patterns on top with the corresponding colours of the spirals (C.L. Dobbs et al. 2012).  

This requires us to search through a huge amount of parameter space;
     two, three, or four spirals,
     a bar or a bulge,
     perhaps two bars,
     how tight do the spirals need to be,
     how fast is it rotating?


So while we are trying to work it out perhaps the engineers can get to work on that Faster Than Light drive so we can zip out and have a look for ourselves.





WHAT'S NEXT?

Thanks to my friend Alex Pettitt for the inspiration for this post as he is one of the poor researchers set to explore this parameter space for his PhD. Also he is much better at explaining this than I am so post any questions and I can see what he says.

Also if you want more information check out these papers and click on the linked segments of the main post. 

The Milky Way in Molecular Clouds: A New Complete CO Survey: http://arxiv.org/pdf/astro-ph/0009217.pdf

The Spiral Structure of the Galaxy: Something Old, Something New... http://adsabs.harvard.edu/abs/2008ASPC..387..375B

Also if you are an engineer get to work on that FTL drive, everyone will thank you.