I marvel at the Cassini spacecraft. It’s incredibly productive, so much so that keeping up can be difficult. In fact, I was all set to write a short piece on a gorgeous image of Saturn just released by the folks at NASA, when another came in before I could even start!
So here you go, two jaw-droppy pictures for the price of one.
The first is a somewhat rare view of Saturn’s north pole, not commonly seen well because Cassini doesn’t spend much time so far north of Saturn’s equator:
This image shows a part of Saturn’s bizarre hexagonal vortex; a six-sided cloud pattern that’s been blowing over the Saturnian arctic for at least three decades. This sort of pattern may seem really strange—and to be fair, it is—but it’s actually a quite natural consequence of spinning fluids. It’s even been reproduced in a lab:
Emily Lakdawalla at The Planetary Society blog has more info. Polar vortices are actually common; the Earth has one, as do several other planets. It’s not really a storm, just a stable wind pattern. This image, taken in the near-infrared, accentuates clouds and highlights features in the planet’s atmosphere.
The second Cassini photo is also quite lovely, but it has a surprise that made me smile in delight:
I like the dynamic angle of Saturn and the rings in this shot, and how it’s framed, too. It’s amazingly dramatic, with the rings curving around the planet, and you can see the fainter inner rings against the planet’s clouds and the darkness of space, too.
But look again, down at the bottom. What’s that bright spot?
It’s real, and due to the “opposition effect”. When light hits tiny particles of ice and rock, it gets bounced off in all directions (this is called scattering). But there’s an effect where more light is scattered directly back in the direction from which it came. You may have seen this before; when you walk along a field of dew-laden grass in the early morning, it appears that the shadow of your head has a bright halo around it. The dew drops send light back toward the Sun, and so the grass that lies on a line with the Sun and your eyes (where the shadow of your eyes falls on the grass, actually) is sending more light toward your eyes, so you see a halo.
Apollo astronauts saw the same thing on the Moon. I’ve seen it, quite strongly, walking across a dusty baseball infield.
That’s what’s happening in this Cassini image, too! The Sun was almost directly behind Cassini when it took that picture, and the tiny particles of ice in the ring are scattering the light back toward Cassini’s cameras, creating that bright spot. It’s called the “opposition effect” because the Sun and the particles have to be opposite each other (180° apart) as seen by the camera or your eyes. It’s also called an “opposition surge” which I think is quite poetic.
This isn’t the first time it’s been seen in Saturn’s rings by Cassini; in 2007 a fantastic picture was released showing it as a rainbow! The spread of colors wasn’t real, but was actually due to a combination of Cassini’s motion and the need to change filters from red to green to blue. When combined, the three images smeared out the colors of the bright spot, producing a multi-hued spot. You can also see the opposition glow at the 3:00 mark in the video embedded here.
Right now as I write this, Saturn is getting closer to the Sun, sinking lower in the western horizon after sunset every day. A few months ago, when it was up and well-placed all night, I delighted in showing many people the ringed wonder through my telescope, and it was always a tremendous moment to watch their eyes go wide when they saw it for the first time. Saturn is amazing, the crown jewel of the solar system, and I’m very glad we have as magnificent a machine as Cassini tending to it.