Everyday life

The Chandra X-ray Observatory and Hubble Space Telescope are two telescopes, orbiting earth, capable of observing in the x-ray and visible regime respectively. Over the years they have produced streams of absolutely stunning images of our beautiful universe. One of the images I like most is a combination of data from both telescopes:

This image of Abell 1689 is a composite of data from the Chandra X-ray Observatory (purple) and the Hubble Space Telescope (yellow)

It shows the enormous galaxy cluster Abell 1689 and apart from being visualy appealing, the image is also full of cool physical effects that I would like to point out. Let’s start with with the purple x-ray glow coming from the center of the massive galaxy cluster. It originates from extremely hot gas in the center of the galaxy cluster. Reportedly, the gravitational forces at play in that region cause the gas to heat to over a 100 million degrees Celsius. Also, the same purple region is predicted to contain large amounts of dark matter (matter we can’t directly measure, but has to be there in order for the gravitational fields to be as they are).

How intens the gravitational fields are in the center region of the cluster is also apparent from another, in multiple ways cooler, physical effect; gravitational lensing. The theory of gravitational lensing relies on Einsteins theory of general relativity. This may sound scary, but as long as we stay away from the math, there is nothing to worry about ;). To illustrate how this effect works I will borrow a figure from elsewhere on the webweb.

https://i0.wp.com/www.physicsoftheuniverse.com/images/relativity_light_bending.jpg

General relativity at work. Source: http://www.physicsoftheuniverse.com

Einstein’s theory of general relativity tells us that spacetime (simply picture this as space) is curved in the vicinity of very heavy objects. The huge galaxy cluster Abell 1689 significantly curves spacetime and this curved spacetime deflects light from its straight path as is illustrated in the image above.

https://i0.wp.com/www.lsst.org/files/img/Soares-Grav_Lens.jpg

Graphical representation of gravitational lensing by a galaxy cluster. Source: http://www.LSST.org

The complex shape of the gravitational field in Abell 1689 bends light from galaxies behind it towards earth so that a single object appears to be at multiple different places at once. Taking into account that this lensing of course distorts the image intensely, what we expect to see are some vague blurry objects with odd shapes that don’t seem to belong there. This is exactly what is visible in the image that this article is about. In the image below (Hubble data only) I have highlighted the lensed images. Look them up in the original image.

Arcs that are lensed images of galaxies behind the galaxy cluster

One more effect I would like to point out is the diffraction due to the telescopic design. The brightest stars in the image are not simply bright dots as one would expect from a spherical star, but look more like crosses. These 4 ‘spikes’ that surround the center star are know as diffraction spikes. They are caused by the structure that supports the secondary mirror in the telescope. This structure is comprised of several (4 in the case of the Hubble Space Telescope) bars that keep the secondary mirror in its place as is shown in the graphic below.

https://i0.wp.com/amazing-space.stsci.edu/resources/explorations/groundup/lesson/basics/g28a/graphics/g28a_hst.gif

Hubble Space Telescope’s optical design scheme

The diffraction is due to the interaction between light passing on either side of the support bars. But how is this possible if light moves in a straight line? Well, as light is not purely particle-like of nature, but also behaves somewhat as a wave, part of the incoming waves may ‘bend around the bar’ a bit. The diffraction pattern shows what is known as the ‘Fourier transform’ of the light. Which means that it shows the spectrum of frequencies present in the incoming light. This is also clearly visible in the image of Abell 1689. Below you see an excerpt of the bigger picture, clearly showing the different colors in the spikes.

$Diffraction spikes due to secondary mirror support bars$

Diffraction spikes due to secondary mirror support bars

Not only the Hubble telescope shows this diffraction pattern, but amateur telescopes with a similar design do to. In fact, my telescope has 3 such bars which shows 6 (albeit less pronounced) diffraction spikes around bright objects. A while ago I imaged Deneb, a blue-white supergiant star weighing about 20 solar masses, and the resulting image showed some cool diffraction spikes.

$Single exposure of blue-white supergiant Deneb. Clearly visible are the 6 diffraction spikes due to the 3 bars that obscure the view.$

Single exposure of blue-white supergiant Deneb. Clearly visible are the 6 diffraction spikes due to the 3 bars that obscure the view.

I hope that after reading this, you can appreciate the image at the top of this post as much as I do 🙂

As I am quite busy with my study at the moment, I haven’t had the time to get out with my telescope. Apart from that, there also isn’t much new to show you this time of the year. You have seen what I can make of the brightest planetary nebula, star clusters and the andromeda galaxy:

: Best 41 frames of all the photos I got of M27 stacked together.

: M13 globular cluster in Hercules

: Bright core of the Andromeda Galaxy

There certainly is lots and lots of more interesting stuff up there, but nothing that’s bright enough for me to be able to photograph with the equipment I have right now. Once I get more time and saved me enough to buy a motorized mount, I will have so much more to show you. Until then, I will wait for Jupiter and the Orion constellation to be up at a reasonable time. I’m sure I can make some cool pictures of those with the setup I have right now.

Even though I haven’t been shooting cool pictures myself, I’ve certainly seen some taken by others that I would to share with you. Starting with this awesome image of the Dumbbell Nebula, M27 (click for supersized image):

Collective image of the Dumbbell Nebula shot by 13 different amateur astronomers: Claudio Bottari, Paolo Demaria, Giuseppe Donatiello, Marco Favuzzi, Andrew Genualdi, Federico Lavarino, Rolando Ligustri (CAST), Andrea Pistocchini, Craig Prost, Christian Riou, Bert Scheuneman, Tim Stone, Rubes Turchetti (CAST)

This image is a result of 13 amateur astronomers that stacked their results (which are stacks of long exposures themselves) together into one image that contains data obtained during what must have been more than 24 hours total. You can actually see the inner star, radiating so intenste that it blows it’s outer shell away. This image is mostly green and red corresponding to Oxygen-III and H-alpha emission respectively.

On the 2nd of September, a group led by the University of Hawaii published how they discovered the structure of our supercluster. Our what? Well you know that the Earth orbits around the Sun right? And that the Sun, together with millions of other stars, orbits a supermassive black hole to form our galaxy, the Milky Way. Together with Andromeda and some 50 smaller (dwarf) galaxies we make up something called the ‘Local Group’: a small group of neigboring galaxies. This little group is in turn part of the Virgo cluster of small groups. Well, Virgo and 2 other galaxy clusters, make up our supercluster and she’s called: Laniakea, which means immeasurable heaven in Hawaiian. Her shape it shown in the image below where our Milky Way is marked with a blue dot.

Our home supercluster: Laniakea

Astronomers have indexed a huge amount of galaxies with their positions and velocities. Subtracting the velocity of the galaxies caused by the expansion of the universe, they were left with the velocities due to gravitational attraction. From their velocities (paths marked by white lines), the astronomers were able to deduce the point all galaxies in our supercluster are heading to, called ‘The Great Attractor’. Great name right?

The Northern lights have been all over the news this week and I have seen a lot of beautiful pictures coming from Canada, Alaska and Scandinavia. The best I’ve seen wasn’t photographed last week, but over a year ago. The photograph also shows a huge meteor crashing through the atmosphere and I just had to post it here.