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  • Written by Shannon Schmoll, Director of the Abrams Planetarium, Michigan State University
Comets 101 − everything you need to know about the snow cones of space

When you hear the word comet, you might imagine a bright streak moving across the sky. You may have a family member who saw a comet before you were born, or you may have seen one yourself when comet Nishimura passed by Earth[1] in September 2023. But what are these special celestial objects made of? Where do they come from, and why do they have such long tails?

As a planetarium director[2], I spend most of my time getting people excited about and interested in space. Nothing piques people’s interest in Earth’s place in the universe quite like comets. They’re unpredictable, and they often go undetected until they get close to the Sun. I still get excited when one comes into view.

What exactly is a comet?

Comets are leftover material from the formation of the solar system. As the solar system formed about 4.5 billion years ago[3], most gas, dust, rock and metal ended up in the Sun or the planets. What did not get captured was left over as comets and asteroids[4].

Because comets are[5] clumps of rock, dust, ice and the frozen forms of various gases and molecules, they’re often called[6] “dirty snowballs” or “icy dirtballs” by astronomers. Theses clumps of ice and dirt make up what’s called the comet nucleus.

A diagram showing comet nuclei, which look like gray rocks, of progressively larger sizes.
Size comparison of various comet nuclei. NASA, ESA, Zena Levy (STScI)[7]

Outside the nucleus is a porous, almost fluffy layer of ice, kind of like a snow cone. This layer is surrounded by a dense crystalline crust[8], which forms when the comet passes near the Sun and its outer layers heat up. With a crispy outside and a fluffy inside, astronomers have compared comets to deep-fried ice cream[9].

Most comets are a few miles wide[10], and the largest known is about 85 miles[11] wide. Because they are relatively small and dark compared with other objects in the solar system, people can’t see them unless the comet gets close to the Sun.

Pin the tail on the comet

Starry sky with a comet in the mid left portion of the image and a tree in the foreground Comet Hale-Bopp as seen from Earth in 1997. The blue ion tail is visible to the top left of the comet. Philipp Salzgeber, CC BY-ND[12][13]

As a comet moves close to the Sun, it heats up. The various frozen gases and molecules making up the comet change directly from solid ice to gas in a process called sublimation[14]. This sublimation process releases dust particles trapped under the comet’s surface.

The dust and released gas form a cloud around the comet called a coma. This gas and dust interact with the Sun to form two different tails[15].

The first tail, made up of gas, is called the ion tail[16]. The Sun’s radiation strips electrons from the gases in the coma, leaving them with a positive charge. These charged gases are called ions. Wind from the Sun then pushes these charged gas particles directly away from the Sun, forming a tail that appears blue in color. The blue color comes from large numbers of carbon monoxide[17] ions in the tail.

The dust tail forms from the dust particles released during sublimation. These are pushed away from the Sun by pressure caused by the Sun’s light[18]. The tail reflects the sunlight and swoops behind the comet as it moves, giving the comet’s tail a curve[19].

The closer a comet gets to the Sun, the longer and brighter its tail will grow. The tail can grow significantly longer than the nucleus and clock in around half a million miles long[20].

Where do comets come from?

All comets have highly eccentric orbits[21]. Their paths are elongated ovals with extreme trajectories that take them both very close to and very far from the Sun.

Comets’ orbits can be very long, meaning they may spend most of their time in far-off reaches of the solar system.

An object will orbit faster the closer it is[22] to the Sun, as angular momentum is conserved[23]. Think about how an ice skater spins faster[24] when they bring their arms in closer to their body – similarly, comets speed up when they get close to the Sun. Otherwise, comets spend most of their time moving relatively slowly through the outer reaches of the solar system.

A lot of comets likely originate in a far-out region of our solar system called the Oort cloud[25].

The Oort cloud is predicted to be a round shell of small solar system bodies[26] that surround the Earth’s solar system with an innermost boundary about 2,000 times farther from the Sun than Earth. For reference, Pluto is only about 40 times farther[27].

Sphere of small particles with a disk like structure in the middle. A tiny rectangle in the center points to a zoomed in image of the Sun and planet orbits A NASA diagram of the Oort cloud’s structure. The term KBO refers to Kuiper Belt objects near where Pluto lies. NASA[28]

Comets from the Oort cloud take over 200 years to complete their orbits, a metric called the orbital period. Because of their long periods, they’re called long-period comets[29]. Astronomers often don’t know much about these comets until they get close to the inner solar system.

Short-period comets[30], on the other hand, have orbital periods of less than 200 years. Halley’s comet is a famous comet that comes close to the Sun every 75 years.

While that’s a long time for a human, that’s a short period for a comet. Short-period comets generally come from the Kuiper Belt[31], an asteroid belt out beyond Neptune and, most famously, the home of Pluto.

There’s a subset of short-period comets that get only to about Jupiter’s orbit at their farthest point from the Sun. These have orbital periods of less than 20 years and are called Jupiter-family comets[32].

Comets’ time in the inner solar system is relatively short, generally on the order of weeks to months[33]. As they approach the Sun, their tails grow and they brighten before fading on their way back to the outer solar system.

But even the short-period comets don’t come around often, and their porous interior means they can sometimes fall apart. All of this makes their behavior difficult to predict[34]. Astronomers can track comets when they are coming toward the inner solar system and make predictions based on observations. But they never quite know if a comet will get bright enough to be seen with the naked eye as it passes Earth, or if it will fall apart and fizzle out as it enters the inner solar system.

Either way, comets will keep people looking up at the skies for years to come.

References

  1. ^ comet Nishimura passed by Earth (www.livescience.com)
  2. ^ planetarium director (msutoday.msu.edu)
  3. ^ 4.5 billion years ago (science.nasa.gov)
  4. ^ left over as comets and asteroids (solarsystem.nasa.gov)
  5. ^ comets are (www.universetoday.com)
  6. ^ they’re often called (adsabs.harvard.edu)
  7. ^ NASA, ESA, Zena Levy (STScI) (hubblesite.org)
  8. ^ dense crystalline crust (www.jpl.nasa.gov)
  9. ^ deep-fried ice cream (www.nasa.gov)
  10. ^ a few miles wide (www.vanderbilt.edu)
  11. ^ about 85 miles (www.nasa.gov)
  12. ^ Philipp Salzgeber (commons.wikimedia.org)
  13. ^ CC BY-ND (creativecommons.org)
  14. ^ process called sublimation (www.britannica.com)
  15. ^ two different tails (skyandtelescope.org)
  16. ^ the ion tail (www.sciencedirect.com)
  17. ^ carbon monoxide (astronomy.swin.edu.au)
  18. ^ pressure caused by the Sun’s light (science.nasa.gov)
  19. ^ the comet’s tail a curve (spaceplace.nasa.gov)
  20. ^ half a million miles long (coolcosmos.ipac.caltech.edu)
  21. ^ highly eccentric orbits (www.st-andrews.ac.uk)
  22. ^ orbit faster the closer it is (solarsystem.nasa.gov)
  23. ^ angular momentum is conserved (www.britannica.com)
  24. ^ ice skater spins faster (news.unl.edu)
  25. ^ the Oort cloud (solarsystem.nasa.gov)
  26. ^ small solar system bodies (science.nasa.gov)
  27. ^ 40 times farther (solarsystem.nasa.gov)
  28. ^ NASA (solarsystem.nasa.gov)
  29. ^ long-period comets (astronomy.swin.edu.au)
  30. ^ Short-period comets (starchild.gsfc.nasa.gov)
  31. ^ Kuiper Belt (solarsystem.nasa.gov)
  32. ^ Jupiter-family comets (astronomy.swin.edu.au)
  33. ^ weeks to months (eyes.nasa.gov)
  34. ^ difficult to predict (www.space.com)

Authors: Shannon Schmoll, Director of the Abrams Planetarium, Michigan State University

Read more https://theconversation.com/comets-101-everything-you-need-to-know-about-the-snow-cones-of-space-213342

Metropolitan republishes selected articles from The Conversation USA with permission

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