At about one-eighth the mass of Pluto, Charon is a satellite
unusually close in mass to the body it orbits. (And also relatively large in relation to the parent body). Since the 1980s, astronomers
have inferred that the binary system formed following the collision of two
proto-bodies. Simulations of the system predicted a formation scenario in which
proto-Charon grazed proto-Pluto, and the system lost enough angular momentum to
match its current state.
Those simulations, however, treated the colliding objects as
fluids. C. Adeene Denton of the University of Arizona wondered whether
that was a reasonable assumption, considering that the proto-bodies that formed
the Pluto–Charon system were smaller and not traveling as fast as other modeled
impactors.
When Denton and her collaborators ran new simulations that factored in the material properties of the proto-bodies’ ice and rock, the colliding bodies deformed less than they did in the fluid simulations. Grazing collisions became hit-and-run events where Charon escaped the system entirely. The simulations indicate that to match current observations of the binary system, proto-Charon would have had to hit proto-Pluto at an almost 45° angle and slightly penetrate Pluto’s interior. Within about 60 hours, Charon would have been pushed away by the angular momentum of Pluto and captured into a close orbit.
Charon (green and purple object) and Pluto (yellow and blue) exchange material following a collision, and the angular momentum of Pluto forces Charon away. The scale bar represents 2000 km. (Figure adapted from C. A. Denton et al., Nat. Geosci. 18, 37, 2025.)
Denton and her team have dubbed the interaction “kiss and
capture.” The formation scenario may help explain when and how Pluto developed
a subsurface ocean, evidence for which has been provided by observations of
Pluto’s surface from NASA’s New Horizons and other missions.
Tidal forces exerted on Pluto by Charon as it retreated from its close
post-capture orbit could have been the source of the heat that melted the ice
and formed the ancient ocean. Data from a future orbiter mission could provide the
detailed understanding of Pluto’s interior needed to support the scenario
suggested by the modeling.
The Kuiper belt contains other bodies in binary systems with
masses that are within a few orders of magnitude of Pluto and Charon’s.
Although no known ones have mass ratios like Pluto and Charon’s, some
scientists have suggested that the binaries share a common formation history.
Denton says she suspects that the kiss-and-capture regime may prove to be a
better fit for their formation than previous theories. (C. A. Denton et
al., Nat.
Geosci. 18, 37, 2025.)
Source: Physics Today, March, 2025, p. 19
See Also:
Brane Space: New Pluto Images Show The World Many Of Us Expected
And:
Brane Space: What's With Pluto's Smaller, Rapidly Spinning Moons?
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