Though ancient cultures often saw comets as harbingers of doom, the cosmic “dirty snowballs” are now viewed as important objects that could help scientists learn more about the early evolution of the solar system.
In November 2014, the European Space Agency’s Philae probe was dropped from the Rosetta spacecraft, becoming the first human-made spacecraft to soft-land on the surface of a comet. Sending a probe to a comet is one thing. But if astronauts were to land on a comet, what would they experience while living there?
In recent decades, NASA and other space agencies have launched several missions to study comets, so anyone visiting a comet would have at least some knowledge about the cosmic bodies.
For instance, in 1986, Europe’s Giotto spacecraft flew into the coma — the large, diffuse cloud of gas and dust around a comet’s core, or nucleus — of Halley’s Comet to capture the first images of a comet’s nucleus. In 2004, NASA’s Stardust spacecraft collected dust samples from the coma of the Comet Wild 2. And in 2005, the Deep Impact collider smashed into the Comet Temple 1 to study the guts of the comet’s nucleus.
Photographs from comet missions have revealed that comet nuclei are quite small, ranging from less than a mile to tens of miles across. Some of them also have irregular shapes, sometimes resembling the end of a dumbbell.
“The reason they are so irregular is because their gravity is so low,” said Althea Moorhead, a researcher with the Meteoroid Environments Office at NASA’s Marshall Space Flight Center. “I think it would be strange to live on a comet for that reason.”
On Earth and other spherical bodies, gravity is directed straight down. But if you were on a dumbbell-shaped comet, gravity might pull you down and to the side, depending on where you were standing, Moorhead told Space.com.
However, that gravitational tug wouldn’t be overwhelmingly strong. The gravity of Halley’s Comet, for example, is about equal to the gravity of Mount Everest if you were to remove the mountain from Earth and deposit it in space — if you were to drop an object from chest level, it would take about two minutes to hit the ground.
“Its gravity is so low that if you can jump 8 inches [20 centimeters] on Earth, you could jump off Halley’s Comet,” Moorhead said, adding that you’d want to be very careful with your physical activities.
Comets, particularly the irregularly shaped ones, could offer up interesting features to explore, such as impact craters or cavities formed from the sublimation of material. But you’d likely get bored rather quickly. “For something like Halley’s Comet, the total surface area is the same as the island of Lanai [in Hawaii],” Moorhead said. Lanai is about 140.5 square miles (364 square kilometers).
Comets are best known for their comas, but these features exist only when the comets are relatively close to Earth. Halley’s Comet, for example, has a coma for only about a year of its 76-year-long orbit around the sun.
Comas form when ice on the surface of the comet’s nucleus turns into gas. For Halley’s Comet, this occurs when it gets within about 3 astronomical units of the sun, Moorhead said. (One astronomical unit, or AU, is the distance between Earth and the sun, or about 93 million miles (150 million kilometers).)
If you were on a comet when it had a coma, the cloud would likely obscure the stars. And during the day (a full day on Halley’s Comet is between 2.2 and 7.4 Earth days), your field of view would be filled with diffuse light, similar to what you’d see when standing in a deep fog, Moorhead said.
Many comets have elliptical orbits, which take them from the Kuiper Belt (a region of the solar system beyond Neptune) to the inner solar system. Because of this elliptical orbit, the temperature you experience on a comet will vary greatly depending on where the comet is in its orbit.
When the Giotto spacecraft visited Halley’s Comet in 1986, the comet was 0.9 AU from the sun and had a surface temperature of about 170 degrees Fahrenheit (77 degrees Celsius). Rosetta, on the other hand, measured a temperature for Philae’s comet, 67P/C-G, of minus 94 F (minus 70 C) in July 2014, when the comet was more than 3 AU (about 279 million miles, or 450 million km) from the sun.
These elongated orbits also mean that the amount of time it would take to call home to Earth would vary greatly, from a few minutes to several hours.
Source: Space.com
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