Minor Planets and Comets
The Solar System is littered with small objects made of rock and ice. These are the comets and minor planets — asteroids, Kuiper Belt objects, and other tiny fragments left over from the time when the Solar System was first born. We can’t witness the birth of the Solar System, but minor planets and comets provide us with a glimpse of the conditions when the planets formed, and the origins of many of the chemicals that made up early Earth.
Our Work
Center for Astrophysics | Harvard & Smithsonian researchers study comets and minor planets in a number of ways:
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Comparing the composition of comets to observations of newborn star systems. Astronomers use the Atacama Large Millimeter/submillimeter Array (ALMA) to identify molecules in the regions around newborn stars, to compare to the chemistry of the surface of comets, which are relatively undisturbed relics of the Solar System’s early days. These observations provide a way to understand the primordial chemistry of the Solar System.
Astronomers Discover Traces of Methyl Chloride around Infant Stars and Nearby Comet -
Studying the way the Sun affects the surface of comets. Using NASA’s Chandra X-ray Observatory, the Smithsonian’s Submillimeter Array (SMA), and other telescopes, astronomers observe the way molecules on a comet’s surface and in its tails respond when bombarded by sunlight and solar wind particles.
Comets ISON & PanSTARRS: Comets in the ‘X’-Treme -
Using the Chandra X-ray Observatory to study Pluto and other icy worlds of the outer Solar System. While it doesn’t emit X-ray light on its own, Pluto reacts relatively strongly to particles from the solar wind, to the point where it shows up in X-ray telescopes. This is similar to comet- or even Mars-like behavior, but Pluto is much farther from the Sun. That reveals new information about Pluto’s atmosphere.
X-ray Detection Sheds New Light on Pluto -
Combining observation and theory to understand how asteroids formed. Rather than being solid rocks, many asteroids are “rubble piles” built out of small fragments of rock and dust. Since the Solar System is mostly empty space, collisions between asteroids are rare, so astronomers look to other explanations to understand how these rubble piles came to be.
Dead Comets and Near-Earth Encounters -
Looking for asteroids and other bodies that may have originated in other star systems, before being kicked out. A possible vagabond astronomers nicknamed ‘Oumumua passed through the Solar System in 2017. Based on its chemistry, it appears to be similar to many objects from the outer Solar System, which may tell us the chemistry of other star systems is like ours.
Small Asteroid or Comet 'Visits' from Beyond the Solar System -
Contributing to robotic space missions, such as the Origins, Spectral Interpretation, Resource Identification, Security, Regolith, Explorer (OSIRIS-REx). OSIRIS-REx is currently orbiting the near-Earth asteroid Bennu, identifying the composition of materials on its surface and the way they react with sunlight. In addition, OSIRIS-REx will scoop up a sample of material from Bennu’s surface to bring back to Earth for laboratory analysis.
Asteroid Mission Will Carry Student X-ray Experiment -
Participating in current and next-generation astronomical surveys that will discover many minor planets and comets in the Solar System. The Pan-STARRS survey is designed to map the sky, and has turned up a number of comets and other objects. The upcoming Large Synoptic Survey Telescope (LSST) will reveal an unprecedented number of small objects in the Solar System, including those in regions of the sky that aren’t regularly observed.
Pan-STARRS Releases Largest Digital Sky Survey to the World
History in the Rock and Ice
The Solar System formed from a cloud of gas and dust about 5 billion years ago, which collapsed into a rotating protoplanetary disk. Over time, the material formed planetesimals: small chunks of rock and ice. Some of those planetesimals collided with each other, eventually growing to become the major planets. However, many stayed small, drifting between the larger worlds. These are the comets and minor planets, which is a catch-all category for everything in the Solar System that isn’t a planet, moon, or comet. The minor planets include the asteroids, Pluto and other icy worlds beyond Neptune, and a diverse host of other bodies.
Minor planets and comets cover a wide range of sizes, shapes, and chemistry, but one thing they have in common: they are potentially pristine — or nearly so — remnants of the protoplanetary nebula. By studying these fragments of history, researchers can determine the atoms and molecules present at the birth of the Solar System.
Comets
Comets are mixtures of ice, rock, and dust, which often loop through the Solar System in very elongated orbits. “Ice” to an astronomer includes volatile materials like carbon dioxide and methane, along with water ice. When comets pass into the inner Solar System, those ices sublimate into gas, forming the familiar distinctive tail. The melting process also kicks up dust particles, forming a second tail that interacts with particles from the solar wind.
While the bright icy tail is the most obvious visible feature, the comet’s nucleus is often very dark, due to the presence of organic molecules. Because comets are probably the most undisturbed planetesimals from the early Solar System, their chemistry is a glimpse at the environment before the planets were born. To put it simply: by looking at comets, we get a peek at the protoplanetary nebula.
Scientists study how sunlight and solar wind particles affect the molecules on the comet surface. Those interactions can generate X-rays, as well as heating the material to produce other sorts of light. That enables researchers to measure various chemical abundances, to compare between comets and with other worlds in the Solar System — including Earth.
Minor Planets, Major Research
There are many types of minor planets, all of which are interesting in their own way. The icy bodies of the outer Solar System, including Kuiper Belt objects (KBOs), are like comets in many ways, but unique in others. For example, Pluto shows signs of changing surface features, which makes it seem more like inner Solar System objects than a pristine remnant from the days planets first formed.
Asteroids typically spend more time close to the Sun than comets do, so most of the ice they may have had near their surfaces is gone. Those changes to asteroid chemistry make them less pristine, but no less interesting as remnants of the planetesimal era of the Solar System.
Researchers are particularly interested in near-Earth objects (NEOs), partly because their proximity to us makes them easier to study, but also because these are potentially hazardous. Various craters on Earth are the scars from impacts in the past, including the famous Chicxulub crater off the coast of Mexico, which either caused or helped speed the extinction of the non-bird dinosaurs. Both the Tunguska event of 1908, which flattened a whole forest, and the Chelyabinsk meteor of 2013 show that even relatively small NEOs can cause noticeable damage.
While astronomers have ruled out immediate danger of global catastrophe, the Solar System is just unpredictable enough that they study potentially dangerous NEOs, including those of smaller size. Part of understanding the risk is seeing how sunlight affects asteroids, moving them slightly in their orbits and changing how they spin. Studying these effects helps not only predict how NEO orbits might change, but also potentially how spacecraft might nudge dangerous asteroids away from Earth in the future.
The Minor Planet Center
The Center for Astrophysics is host to the Minor Planet Center, a research center focused on studying and tracking asteroids, along with comets, moons, and other minor planets in the Solar System. It’s a clearinghouse of measurements of the orbits and properties of these worlds, along with regular news updates on discoveries made by amateur and professional scientists all over Earth.