The northern lights are a phenomenon that appear in the sky when charged particles coming from the sun slam into oxygen and nitrogen molecules in the atmosphere, ionizing those molecules and causing them to glow. These lights can only typically be seen at high northern latitudes, and they can vary from a weak glow on the horizon to billowing green and red sheets covering the sky.
The northern lights come in a variety of shapes and colors. The most common form is a general whitish "haze" or static glow just above the horizon. In more spectacular shows, the lights can be seen directly overhead as they form billowing, undulating curtains and sheets of blue, green and red. The red — the rarest of the colors — comes from highly energized particles striking oxygen in the upper atmosphere. The blues and greens come from particles hitting nitrogen in lower levels of the atmosphere, according to NASA.
Despite popular misconceptions, it doesn't have to be cold out to see the northern lights. But they can only be seen at night, and at the northernmost latitudes where there is little — and sometimes no — daylight during the winter months, so to go hunting for northern lights you're generally going to need to bring some layers.
That said, sometimes the northern lights can stretch south. Here's how: The charged particles from the sun are called the "solar wind," and they are constantly streaming through the solar system.
These charged particles get caught up in the Earth's magnetic field, which funnels some of them to the north pole and some to the south poles, where they slam into our atmosphere, creating the remarkable display. So the northern lights are matched by southern lights, but since it's much more difficult to visit the Antarctic, the northern lights are much more commonly viewed.
When the sun is cycling through a more active phase, the solar wind can become much stronger. Also, sometimes the sun releases an enormous number of particles all at once in an event called a coronal mass ejection. During those events, the northern lights will appear much brighter and can be seen farther south, because the excess charged particles overwhelm the usual funnel system of the Earth's magnetic field, according to the Space Weather Archive.
Even the Greeks, who almost never experienced the northern lights themselves, knew about them from travelers and traders, and they were described by the fourth-century explorer Pytheas.
Galileo thought the northern lights were caused by sunlight reflecting off of high-altitude clouds, and Benjamin Franklin theorized that they were caused by concentrations of electrical charge. In 1741, Swedish astronomer Olof Hiorter observed a compass needle rhythmically swing back and forth in time with the undulations of the lights, confirming that magnetic fields were also involved. However, it wasn't until the early 1900's that Norwegian scientist Kristian Birkeland first outlined the connection between solar charged particles, the elements in the atmosphere, and the northern light shows, according to a British Antarctic Survey site.
Earth isn't the only planet to host northern lights. Jupiter and Saturn have magnetic fields stronger than Earth's, so they have truly impressive displays. Even Uranus and Neptune, far from the sun, host northern lights. Weak northern lights have been detected on Mercury, Mars and even Venus. The last is remarkable because Venus doesn't have a magnetic field, so that planet's northern lights appear as diffuse patches throughout its atmosphere.
Astronomers hope to identify northern lights outside the solar system. The most likely candidates are brown dwarfs, which are bodies larger than planets but smaller than stars. According to Joachim Saur, a geophysicist at the University of Cologne, the northern lights on brown dwarfs are expected to be a trillion times brighter than they are on Earth.
The northern lights on brown dwarfs would be so strong that they should appear in ultraviolet radiation (UV), making them relatively easy to detect. "Brown dwarfs are relatively cold objects," Saur told Live Science. "Therefore, they do not emit thermal UV, which the sun for example does. Therefore, brown dwarfs are ideal objects to search for UV aurora outside the solar system, as there is no competing UV emission expected."