Asteroid Eros as Real Estate?

Eros

Since the only other astronomical body that humans have set foot on is the moon, few laws have been put into place governing who can own what in outer space. Believe it or not, people have tried to claim full ownership of astronomical objects. A man by the name of George W. Nemitz actually tried to claim the near-Earth asteroid Eros as his property! Here's the story: Nemitz worked for a company which helped construct the Near-Earth Asteroid Rendezvous Probe Shoemaker, which landed on Eros in 2000. Nemitz claimed that since he helped build the spacecraft, he could claim ownership of whatever body it landed on, under the Homestead Principle. This principle states that if you discover a new piece of land that is not owned by another person or government (and I'm sure law makers were implying a piece of land on Earth), and you make use of it in some way, you can claim ownership. Thus, Nemitz dubbed Eros as a "spacecraft parking facility" and mailed NASA a $20 parking ticket for landing their spacecraft on "his" asteroid! Can you believe that? To Nemitz's dismay, NASA refused to pay the parking ticket, and a court judge dismissed his case. 

Image Credit:NEAR PRoject, NLR, JHUAPL, Goddard SVS, NASA

How Big is the Universe?

To put it bluntly, the universe is absolutely huge! The study of Cosmology, or how the universe was created and how it has evolved, has revealed some very interesting facts. We now know that the universe is expanding at an increasing rate, and that the universe seems to be roughly uniform. The approximate size of the visible universe is 10^24 miles wide! That's 1,000,000,000,000,000,000,000,000 miles! The image below represents what we believe the universe looks like. Every white spec in the image represents a galaxy, and there are over 350 billion of them! But notice how uniform it looks; there doesn't appear to be any distinct clumps of matter, its all equally spread out. This is somewhat expected  via the current cosmological theories, but also curious. Why should the universe be uniform? What properties of the beginning of the universe lead to this result, and how precise must they have been produce a uniform universe? Cosmologists are working hard on answering these questions, as astronomers continue to probe the most distant parts of the universe!

 Image credit: atlasoftheuniverse.com

Galaxy Superclusters

We live in the Milky Way Galaxy, a beautiful spiral armed galaxy filled with hot gas and young stars.

Did you know that many galaxies, including the Milky Way, actually formed in clusters? Galaxy clusters are groups of 30 or more galaxies that are all gravitationally bound to each other. Galaxy clusters nearby one another can form a supercluster of galaxies, though they may not all be gravitationally bound, just spatially coincident with each other. The Milky Way is part of the Local Group, which contains roughly 40 galaxies. This group is a sub-portion of the Virgo supercluster, which contains over 2500 galaxies within 100 million light years of us! These clusters contain spiral galaxies, like the Milky Way, but also elliptical galaxies which are disk shaped collections of older stars. Some popular clusters you may have heard of are the Fornax cluster, which also lies inside the Virgo supercluster, and the Coma cluster, which is a separate cluster of over 1000 galaxies located over 300 million light years from us. The image above shows some of the superclusters of galaxies in the Universe, with the Virgo cluster at the center. Each white dot is an entire galaxy, so those white regions throughout the image are collections of hundreds of galaxies! 

Image Credit: R. Powell

What Does An Astrophysicist Do?

Apologies for the hiatus in posts these last few weeks, life and work have been very busy. Since I've been swamped with so much work, I thought I'd take the time in this post to describe what  an astronomer or astrophysicist does on a daily basis.

When you think of life as an astronomer, the first thing that comes to mind is telescopes and star parties. You imagine the scientists out late at night staring through their telescopes and taking notes about what they see. While this part of the job, astronomers have much more to do. Graduate students and professors in astronomy spend most of their time teaching, doing research and applying for grant money. They teach or assistant teach college courses, and are constantly writing proposals to different organizations asking for money to fund their research. But what does "doing research" actually mean? In astronomy, research can mean one of three things: taking images with a telescope  and analyzing them using a computer (observational astronomy), writing computer programs to simulate interactions between objects in outer space (theoretical astronomy), or building telescopes, cameras, and detectors for astronomers to use (instrumentation). The first two require you to sit at a computer most of the day and  write computer programs to perform certain tasks. Observational astronomers also spend a lot of time applying for observation time on both space and ground based telescopes. If their proposals are accepted, they receive images from the telescope that they can then analyze to understand the physics and properties of the objects they are looking at. Theoretical astronomers are more like physicists or mathematicians.  They think of a situation that might occur in outer space, write down all of the physics equations  that govern the system, and write computer programs to simulate what's going on. Then they can compare their results with real observations to see if they are correct! The last group of astronomers spend most of their time in labs, building and testing devices for other astronomers to use. This is a more hands on job, and takes just as much engineering skill as it does astronomy knowledge. If it weren't for these people building nice cameras and telescopes, astronomers would be out of a job!

Aside from doing actual science, astronomers spend a good amount of time writing papers about their findings, doing community outreach, and presenting their work at conferences and colleges around the world. Being an astronomer is a lot of work, but also a lot of fun. It's a fast paced and never ending job, and there is always more to learn about outer space!

How Old is that Star?

Determining the age of a star is not as easy as you might think. Since we can't ask a star how old it is, we have to guess the stars age by its appearance. And just like with humans sometimes looks can be deceiving! 

 

There are many ways to determine the age of a star, and today we will discuss stellar models. Like we've discussed before, stars can be placed on an Hertzsprung-Russel (HR) diagram. To do this, you need to measure the stars brightness, or luminosity, and you also need to know what type of star it is. Is it a big, hot blue star,? A cool, small, red? Somewhere in between? Astronomers can determine this by looking at a star's spectrum, or distribution of light, with a telescope. Once we know these two things, we can place the star at the proper position on the HR diagram. Astronomers have been hard at work modeling how stars form, and how their size, temperature, and brightness changes as they age. They have developed paths or lines that are placed on the HR diagram which show a stars path on the graph as it ages. There are models for before the star has reached the main sequence, and after. Basically what you do, is place the star on the HR diagram, see which line it is closest too, and that tells you the stars size and age. Here is an example of how this works. The graph above shows brightness vs. temperature, and models (solid lines) for stars of different masses. Stars, in theory, follow one solid line path going right to  left as it ages. The star represents the spot on the diagram where some arbitrary star's properties are. Based on its position, the star is probably about 4 times the mass of the sun, and about 200,000 years old! This is before it has started hydrogen burning, and is still a "baby" star. You can follow the same method with different models and estimate the age of a star that is burning hydrogen, or on its way towards death.

Discovery of Uranus' Rings

We have discussed before that all the gas planets in the solar system have rings.  Even through a small telescope Saturn has visible rings, but Jupiter, Uranus and Neptune do not. So how did astronomers discover their rings in the first place?

Hubble image of Uranus and its rings

The rings around Uranus were discovered in 1977. Astronomers knew that Uranus was going pass in front of a distant star in the night sky, from Earth's perspective. They pointed their telescopes to towards the planet each night, and expected to see the planet block the light from the star only when the star was directly behind the planet. What they actually observed was the star flickering right before and right after is passed behind the planet. This meant that there must be some unseen object near the planet blocking the starlight! The only plausible explanation was that Uranus has very thin, dim rings that are not visible from telescopes here on Earth. In 1986, Voyager flew by Uranus and imaged the rings for the first time, proving  their existence. Since then, we have discovered rings around Jupiter and Neptune in similar ways.

NASA Missions Extended

 

Artists conception of Spitzer, Planck and Kepler (left to right)

Astronomers received some great news a few days ago. Three major space telescopes, Kepler, Spitzer and Planck, have had their missions extended! This is great news, as astronomers will obtain more data and hopefully make some big discoveries! But what can we do with these telescopes?

The Kepler Space Telescope is an optical telescope has been actively searching for exoplanets. It looks at the same region of the sky 24/7, and measures the brightness of 150,000+ stars. If one of them dims for a short period of time, it might be due to a planet crossing in front of the star and blocking the light. Kepler has already found over 2000 potential exoplanets in the last 2.5 years of operation, and it's funding has been extended until 2016

The Spitzer Space Telescope is an infrared telescope that has been operating since 2004. For the telescope's detector to work properly, it needs to be kept extremely cold. Unfortunately, the cryogenics which keep it cool have run out, but the detector still functions, and some science can be done with the telescope. Astronomers have used Spitzer to look at young stars, distant galaxies, and many other objects that are "hidden" behind giant clouds of gas.  It will continue to operate for another two years.

Planck is a jointly funded NASA and ESA telescope which has been operational for about three years. It's a space based microwave/radio telescope whose main purpose is the study the cosmic microwave background. This is the first light emitted by the universe after the Big Bang. It will help us understand how the universe began by observing it right after it was born. Astronomers also use Planck to study distant galaxies, and objects in our solar system.

Image Credit:  NASA/JPL-Caltech