How to Find the Ice Giants
If you already know what Uranus and Neptune look like, and just need charts to find them, skip to the bottom of this article. But if you've never seen Uranus or Neptune before, it's helpful to know how they were discovered in the first place. Every time you set out to find a new object, you are in some sense reliving the original discovery.
The Discovery of Uranus
In 1779, an obscure amateur astronomer named William Herschel decided to view all the bright stars in the sky at high magnification, to see if they were double stars. Two years into this project, on March 13, 1781, he noticed a "star" in Taurus that looked quite different from all other 6th-magnitude stars when viewed at 227× in his homemade 6.2-inch reflecting telescope. When he observed it again four nights later, it had moved with respect to the background stars, proving that it was actually an object inside our solar system. At first, he assumed that it was a comet.
When professional astronomers viewed Herschel's "comet," they saw only a garden-variety star. That's because unknown to him or anyone else Herschel's homemade reflector was far superior to most professional scopes. But it was easy to watch Herschel's object moving from one night to the next, and that allowed mathematicians to compute its orbit. It turned out to take a nearly circular path around the Sun, just like all the known planets, and very unlike the elongated orbits of comets. And the new object was much farther from the Sun than any solar-system body had ever been seen before. Considering how bright it appeared, it must be many times bigger than Earth.
Herschel had in fact found the planet that we now call Uranus the first new planet discovered throughout all of human history. It was the most revolutionary discovery since Galileo spotted the moons of Jupiter 170 years earlier. Herschel became an instant celebrity and got a stipend from the King of England that allowed him to become a full-time astronomer.
In Herschel's Footsteps
As the story of its discovery indicates, Uranus is easy to see, but not so easy to recognize as a planet. If you're willing to use our charts to identify the planet taking it on faith that we're telling the truth then you won't need any tools besides binoculars. In fact, you might be able to see Uranus with just your unaided eyes if your sky is very dark.
But you'll need to examine the planet quite carefully with a telescope at 100× or higher to see that it's actually a tiny disk rather than a pinpoint of light like a star. That means that you need to pinpoint its location precisely. Being in the right general vicinity isn't good enough. It's easy to scan right over Uranus without noticing that it's anything but a regular star. Remember many generations of highly skilled observers before Herschel did precisely that.
The first step is to make sure that the planet is above the horizon and preferably fairly high in the sky when you plan to look for it. From January through May, Uranus is so close to the Sun that it's difficult or impossible to spot. You can see Uranus as early in the year as June if you're willing to get up before dawn, but the best time to view it in the evening sky is from September through November. December's OK too, but you'll have to start right after sunset.
Uranus is easy to locate if you have a telescope with an accurate Go To mount; otherwise, you'll need the charts at the bottom of this article. And if you need to brush-up your chart-reading skills, you might want to look at our online article Using a Map at the Telescope.
You may be able to recognize Uranus just by its hue, which most people find faintly blue or green. I can see the color even with my 10×50 binoculars. Through a telescope, even at magnifications too low to see that planet's disk, you may notice that it shines with a steadier light than other similarly bright stars. And at 120× in my 70-mm telescope, I can quite clearly make out a tiny disk or dot about the size of the period at the end of this sentence. Don't expect to see any features on the planet, though. Even giant professional telescopes can barely do that.
The Discovery of Neptune
Once Herschel had overturned the millennia-old wisdom that there were exactly five planets besides Earth, astronomers started actively searching for new ones. And indeed, four new planets were discovered between 1801 and 1807, all orbiting between Mars and Jupiter. But these were tiny compared to Earth, let alone Uranus too small to show as extended disks through most telescopes. Herschel, by then the grand old man of astronomy, called them asteroids because they look just like stars (Latin astra). Asteroids' rapid motion with respect to the "fixed" stars makes them great targets for backyard telescopes, but that's a subject for another article.
It wasn't until 1846 that another really large planet was found. And Neptune, as the new planet came to be called, was found in much the same way that you're going to find it. J. G. Galle and H. L. d'Arrest, staff astronomers at the Berlin Observatory, looked where the new planet was predicted to be, compared what they saw with a star chart, found an uncharted star, and then verified that it was in fact a planet.
But credit for the discovery goes not to the astronomers who first saw Neptune but to Urban Jean Joseph Le Verrier, who predicted where it would be found. It had been known for some time that Uranus didn't move exactly as it should, taking the gravitational attraction of the Sun and the known planets into account. Le Verrier analyzed the discrepancy, concluded that it must be due to the pull of a large planet well outside Uranus's orbit, and predicted the new planet's location with an error of just one degree. It was a stunning triumph for theoretical astronomy.
See Neptune for Yourself
Neptune is now about one month ahead of Uranus, best visible in the evening sky from August through October. The two planets are near-twins in actual size, but Neptune is about 50% more distant, which makes it surprisingly much harder to find. But if you can find Uranus, you can find Neptune too, with the aid of the charts below. It just requires using the same techniques more carefully.
Neptune varies from magnitude 7.8 to 8.0, about two magnitudes fainter than Uranus. It's visible in steadily-supported binoculars, but only if you look quite carefully. And while Uranus is frequently brighter than any other star visible in the same binocular or finderscope field, the sky is crowded full of stars as bright as Neptune. So you have to be careful when you match up your charts with what you see through the eyepiece.
Having said all that, it's worth remembering that even a very small telescope can easily show stars down to eighth or ninth magnitude. So Neptune is not faint by telescopic standards. In fact, it's bright enough to stimulate color vision through any telescope with 4 inches (100 mm) of aperture. Look for a hue quite similar to Uranus's, though somewhat bluer.
Neptune's disk is plainly visible at 200× through a 6-inch telescope on a night of steady seeing. But it may be quite hard to see the disk if conditions are bad or your telescope is improperly collimated. My 70-mm refractor is a little too small to resolve Neptune properly, but if I examine the planet carefully at 120× it looks clearly different from a star of similar brightness. Neptune's light is distinctly steadier, and it appears more solid. Not exactly a disk, but a fat pinpoint. But don't take my word for it; see for yourself what Neptune looks like!
Because Uranus and Neptune are so far from the Sun, they move very slowly across the celestial sphere. They appeared side-by-side in 1993, and they've only drifted about 30° apart since then. So they're still visible at more or less the same time of year and/or night. Get charts for the June 2013 - March 2014 season.
If you're looking for a real challenge, try looking for the moons of Uranus.