I feel like I’ve been covering a lot of stories on magnetic fields over the past few months. Fields around the Earth, the Sun, Mars, Jupiter’s Moons, and exoplanets are just some of the places in the universe where we are looking at magnetic field behaviour. The intention is to use our understanding of magnetism to figure out what is inside these worlds, and how they interact with their space environment. You would expect us to understand the Earth’s magnetic field and interior very well, after all, we are stuck here. But it turns out it’s very difficult to study the interior of...
Jupiter has aurora. It’s not surprising since it has a very powerful magnetic field. It’s only natural that the two largest structures in the solar system, the Sun’s solar wind influence (called the heliosphere) and Jupiter’s magnetosphere, should be constantly battling. But don’t expect to see Jupiter’s aurora through a backyard telescope. The result of this battle is far more energetic, producing an aurora invisible to the human eye, one made of X-rays. The Sun constantly blasts charged particles off into space in all directions, assaulting the planets, moons, and other solar system bodies. It is this blast of solar wind that gives...
Exoplanets are light years away, hidden by their parent stars, and barely detectable. Yet even though most have never been directly imaged, we can study the light from the parent star as the planet passes in front of it, and use this information to learn about the planet’s size and composition, especially if it has an atmosphere. Once you know a little bit about how big and dense a planet is, and the major elements that form it’s crust and atmosphere, you can do a lot of Chemistry to figure out what it should be made of and how these...
Deep within the Earth, far below the layers of rock that form the crust, and even further below the molten rock of the mantle, lies a hot core of Iron and Nickel. The swirling of the liquid metal creates a flow of charge and produces the magnetic field of the Earth, without which we humans could not survive. But there is still more. At the centre of the Earth, a part of the liquid metal core, the size of Pluto, cooled into a solid ball of Iron and Nickel. When in the Earth’s history did it form? This question has...
I see so many amazing discoveries from educational institutions around the world, as they do cutting edge research in a variety of space-related fields. But I am truly excited when a discovery is made close to home, at a university here in Ontario, Canada. A PhD candidate from Queen’s University named Matt Schultz has discovered the first ever massive binary star in which both stars have magnetic fields, a star called epsilon Lupi. Why is this a big deal? Well if you’ve done a bit of astronomy in school, you’ll know that stars like the Sun have huge magnetic fields....
The surface of the Sun is around 5500 degrees Celsius. It’s hot, and it’s a completely different state of matter than the solid, liquid, and gas states that we are used to. However, this is a pretty balmy temperature compared to the solar atmosphere, which is heated to over a million degrees. But how does it get so hot compared to the surface? We know the core of the Sun, where fusion happens, is where temperatures can reach 14 Million degrees, but how is that energy radiated outward? And more importantly, how does it bypass the solar surface and make...
The Moon has clearly seen some stuff. It’s visibly heavily cratered across it’s surface, which has remained unchanged since it’s surface solidified 4.2 Billion years ago. Think about that – the Moon has been the same, with the exception of cratering, for 4 Billion years. This is a stark contrast to the Earth, whose erosion and tectonic activity cause the crust to change on scales of a few hundred million years. Astronomers have worked hard to learn about the early solar system by looking at the Moon and its cratering patterns. Most of the visible craters on the Moon are...
The sun is definitely hitting its usual ‘rebellious’ phase on its 11 year sunspot cycle, where it flares up at literally everything. The biggest sunspot observed in 24 years has been releasing huge amounts of energy, in the form of X-class solar flares. In the past week this sunspot, designated AR 12192, has released 3 X-class flares, including a huge X-3.1 on Friday. NASA’s Solar Dynamics Observatory (SDO) has been watching the light show. Okay so the Sun is blowing up, what does all this mean? Let’s start with Sunspots. A sunspot is a place on the sun where there...