Massive stars and low-mass stars live different lives. They are born in different environments, fuse different elements during the course of their lives, release different amounts of radiation across the electromagnetic spectrum, die in different ways, and enrich interstellar space with different metals. We see stars at all stages of life in the galaxy, and their study allows us to piece together how stars form, and how the rarest ones are different. The image above shows two distinct clouds, both about 5,000 light years away in the constellation Cygnus, along the Galactic plane. The smaller bubble on the left, literally...
Data is beautiful. There is elegance in the artful manipulation of data to communicate information. I love to see new ways to communicate science to the layman and give an understanding of the collective human knowledge. So I had to post this timeline of the universe infographic, containing events from the beginning of the universe all the way up to the death of the Sun. This is obviously just the tip of the scientific iceberg so to speak, but some of the highlights chosen cross several disciplines of science and are truly significant events in history. Enjoy the truly beautiful...
What do other planetary systems look like? We have seen some where massive Jupiter-sized worlds orbit closer to their star than Mercury does to the Sun, baking them with radiation. Others have had multiple rocky planets within the Earth’s orbit distance. Some have planets similar to Earth in a variety of locations. But what about far away from the star? We never expected to find gas giants like Uranus and Neptune in the far reaches of our solar system. Are there planetary systems where planets live even farther away? Maybe there are planets that live in the empty darkness between stars,...
The only reason we can see black holes in the universe is because some of them swallow up gas and dust. This heats up material that is spinning rapidly around the black hole as it falls in (called an accretion disk), and produces massive jets of material due to conservation of angular momentum that can be seen across the universe. The energy released in the jets and the energy given off in the accretion disk are proportional to how much gas and dust is being consumed by the black hole. More matter = more food = more energy released. But...
How do the Mars rovers compare in size and features? Here’s a great photo putting it all into perspective. Included are Sojourner, Spirit/Opportunity, and Curiosity, with a couple of testing officials at NASA’s Jet Propulsion Laboratory. These are not the rovers that were sent to Mars, but are the secondary ones built for testing here on Earth. They cost a lot of money to build too, so NASA keeps them nice and safe.
Inhabited entirely by robots, Mars is the enigmatic planet that is under intense exploration by humanity. The curiosity rover has been making it’s way closer to Mount Sharp in the Gale Crater, intending to slowly climb the mountain, sampling rocks from different eras in Mars’ history along the way. One of the last regions to cross before beginning its ascent is the region known as the Bagnold dunes, strange dark features similar to sand dunes on Earth. Photos from Curiosity show the beauty and detail in the dark features. The dark dunes have very interesting ripple features, similar to those...
There are so many little things about gravity that we take for granted. If you take it away, a lot of things become tougher. The common discussion points are how you lose bone density, muscle mass, you get taller, and increased risk of herniated disks. But there are a lot of day to day things that are tough too. Sleeping while having no concept of up and down, exercising without weights, eating, writing, and drinking. Generally astronauts would have to drink from bags because you simply couldn’t have a cup of water. The lack of gravity would have the water...
How do stars lose mass? For a star like the Sun, it shoots out a swath of charged particles into space and sheds mass at a rate of 4 million tons per second! Though even at this rate, the Sun only loses 1% of its total mass every 160 Billion years, so it’s not disappearing anytime soon. For more massive stars, the process can become complex and strange. The red hypergiant VY Canis Majoris, one of the largest known stars, is about 40 times as massive as the Sun, but humungous in scale. If this star were to replace the...
As someone who is a hobbyist astrophotographer, I’ve got a laundry list of astronomical events to photograph. Nebulas, Galaxies, star clusters, eclipses, and of course, aurorae! Where do the best aurorae happen? Near the north and south poles, so naturally it makes sense to visit those places where there is a bit of civilization, far north or south, with clear skies. The two places that are on my top list, outside of northern regions in my home country of Canada, are Iceland and Norway. Here are some reasons why: The aurora borealis are legendary in these parts of the world....
The Past: Mars has water, and it used to have a lot more. If modern Mars had the ocean it once had, it would evaporate off into space quickly because there is no heavy atmosphere to help keep it pressurized and in liquid form. Mars would have had a thicker atmosphere in addition to it’s magnetic field in order to keep all that water in one place. So where did the atmosphere go? And if there was such a thick atmosphere, how does it account for the fingerprint of excess Carbon-13 and a lack of Carbon-12 found on the red planet...