Science News
from research organizations

Two chaotically tumbling Pluto moons

Date:
June 3, 2015
Source:
Space Telescope Science Institute (STScI)
Summary:
If you lived on one of Pluto's moons Nix or Hydra, you'd have a hard time setting your alarm clock. That's because you could not know for sure when, or even in which direction, the sun would rise. Comprehensive analysis of data from NASA's Hubble Space Telescope shows that two of Pluto's moons, Nix and Hydra, wobble unpredictably.
Share:
FULL STORY

Artist's illustration of the chaotic spin of Pluto's moon Nix. This set of computer modeling illustrations of Pluto's moon Nix shows how the orientation of the moon changes unpredictably as it orbits the "double planet" Pluto-Charon. This illustration is based on dynamical models of spinning bodies in complex gravitational fields -- like the field produced by Pluto and Charon's motion about each other. Astronomers used this simulation to try to understand the unpredictable changes in reflected light from Nix as it orbits Pluto-Charon. They also found that Pluto's moon Hydra also undergoes chaotic spin. The football shape of both moons contributes to their wild motion. The consequences are that if you lived on either moon, you could not predict the time or direction the sun would rise the next day. (The moon is too small for Hubble to resolve surface features, and so the surface textures used here are purely for illustration purposes.)
Credit: NASA, ESA, M. Showalter (SETI Inst.), D. Hamilton (Univ. of Maryland, College Park), and G. Bacon (STScI)

If you lived on one of Pluto's moons Nix or Hydra, you'd have a hard time setting your alarm clock. That's because you could not know for sure when, or even in which direction, the sun would rise.

A comprehensive analysis of all available Hubble Space Telescope data shows that two of Pluto's moons, Nix and Hydra, are wobbling unpredictably. Scientists believe the other two small moons, Kerberos and Styx, are likely in a similar situation, pending further study.

"Hubble has provided a new view of Pluto and its moons revealing a cosmic dance with a chaotic rhythm," said John Grunsfeld, associate administrator of NASA's Science Mission Directorate in Washington, D.C. "When the New Horizons spacecraft flies through the Pluto system in July we'll get a chance to see what these moons look like up close and personal."

Why the chaos? Because the moons are embedded inside a dynamically shifting gravitational field caused by the system's two central bodies, Pluto and Charon, whirling about each other. The variable gravitational field induces torques that send the smaller moons tumbling in unpredictable ways. This torque is strengthened by the fact the moons are football shaped rather than spherical.

The surprising results of the Hubble research, conducted by Mark Showalter of the SETI Institute in Mountain View, California, and Doug Hamilton of the University of Maryland at College Park, are appearing in the June 4 issue of the British science journal Nature.

"Prior to the Hubble observations nobody appreciated the intricate dynamics of the Pluto system," Showalter said. "Our report provides important new constraints on the sequence of events that led to the formation of the system."

Hubble's monitoring of Pluto's four outer moons has also revealed that three of them, Nix, Styx, and Hydra, are presently locked together in resonance where there is a precise ratio among their orbital periods. "This ties together their motion in a way similar to that of three of Jupiter's large moons," noted Hamilton. "If you were sitting on Nix you would see that Styx orbits Pluto twice for every three orbits made by Hydra."

Hubble provides observational evidence that the satellites are also orbiting chaotically. "However, that does not necessarily mean that the system is on the brink of flying apart," Showalter added. "We need to know a lot more about the system before we can determine its long-term fate."

To the surprise of astronomers, Hubble also found that the moon Kerberos is as dark as a charcoal briquette, while the other satellites are as bright as white sand. It was predicted that pollution by dust blasted off the satellites by meteorite impacts should overcoat all the moons, giving their surfaces a homogeneous look. "This is a very provocative result," Showalter said.

NASA's New Horizons probe, which will fly by the Pluto-Charon system in July 2015, may help settle the question of the asphalt-black moon as well as the other oddities uncovered by Hubble. These new discoveries are being used in the science planning for the New Horizons observations.

The chaos in the Pluto-Charon system offers insights into how planets orbiting a double-star might behave. "We are learning that chaos may be a common trait of binary systems," Hamilton said. "It might even have consequences for life on planets in such systems." NASA's Kepler space observatory has found several planetary systems orbiting double stars.

Clues to the Pluto chaos first came when astronomers measured variations in the light reflected off of the two moons Nix and Hydra. Their brightness changed unpredictably. "The data were confusing; they made no sense at all. We had an inkling something was fishy," Showalter said. His team analyzed Hubble images of Pluto taken during 2005-2012. They compared the unpredictable changes in the moons' reflectivity to dynamical models of spinning bodies in complex gravitational fields.

Virtually all large moons, as well as small moons in close-in orbits, keep one hemisphere facing their parent planet. This means that the satellite's rotation is perfectly matched to the orbital period. This is not coincidental, but the consequence of gravitational tides between moon and planet. (Hyperion, which orbits Saturn, is the only other solar-system example of chaotic rotation; it is due to the combined gravitational tugs of the planet and it largest moon, Titan).

Pluto's moons are hypothesized to have formed by a collision between the dwarf planet and another similar-sized body early in the history of the solar system. The smashup flung material that coalesced into the family of satellites observed around Pluto today. Its large binary companion, Charon, was discovered in 1978. The object is almost half the size of Pluto. Hubble discovered Nix and Hydra in 2005, Kerberos in 2011, and Styx in 2012. These little moons, measuring just tens of miles across, were found as part of a Hubble search for potential hazards to the New Horizons spacecraft flyby.

Pluto and Charon are called a double planet because they orbit about a common center of gravity that is located in the space between the bodies. Some regard the Earth-moon system as a double planet, too, although the center of gravity falls beneath Earth's surface. (Our moon has 1/80th of Earth's mass, whereas Charon has 1/8th of Pluto's mass.)

Researchers say that a combination of monitoring data from Hubble, New Horizons's brief close-up look, and eventually, observations with the James Webb Space Telescope will help settle many mysteries of the Pluto-Charon system. No ground-based telescopes have yet been able to detect the smallest moons.

"Pluto will continue to surprise us when New Horizons flies past it in July," Showalter said. "Our work with the Hubble telescope just gives us a foretaste of what's in store."


Story Source:

Materials provided by Space Telescope Science Institute (STScI). Note: Content may be edited for style and length.


Journal Reference:

  1. Showalter, M. R. & Hamilton, D. P. Resonant Interactions and Chaotic Rotation of Pluto ’ s Small Moons. Nature, 2015 DOI: 10.1038/nature14469

Cite This Page:

Space Telescope Science Institute (STScI). "Two chaotically tumbling Pluto moons." ScienceDaily. ScienceDaily, 3 June 2015. <www.sciencedaily.com/releases/2015/06/150603130447.htm>.
Space Telescope Science Institute (STScI). (2015, June 3). Two chaotically tumbling Pluto moons. ScienceDaily. Retrieved May 8, 2017 from www.sciencedaily.com/releases/2015/06/150603130447.htm
Space Telescope Science Institute (STScI). "Two chaotically tumbling Pluto moons." ScienceDaily. www.sciencedaily.com/releases/2015/06/150603130447.htm (accessed May 8, 2017).