Chris Peterson wrote:geckzilla wrote:
I could think of some circumstances that would allow for moons to have moons. There's definitely nothing about physics that makes it impossible once you're at some nth level of of orbiting bodies.
Not impossible, no. But whenever you have more than two bodies orbiting, you have an unstable situation. No doubt, planetary moons occasionally capture bodies which become their own moons. But the odds of everything working out so that the resulting orbit is stable over millions of years is very small. So over our narrow temporal window of observation, it's not surprising we don't see them.
Any moon tidally locked to it's planet is very unlikely
to have a moon of it's own (in the traditional sense of the word).
Code: Select all
Parent Body Tidally-locked Satellites
---------------------------------------------------------
Earth Moon
Mars Phobos · Deimos
Jupiter Metis · Adrastea · Amalthea · Thebe · Io · Europa · Ganymede · Callisto
Saturn Pan · Atlas · Prometheus · Pandora · Epimetheus · Janus · Mimas
Enceladus · Telesto · Tethys · Calypso · Dione · Rhea · Titan · Iapetus
Uranus Miranda · Ariel · Umbriel · Titania · Oberon
Neptune Proteus · Triton
Pluto Charon
The most likely moons to have moons in our solar system are those
distantly orbiting small captured asteroids of the outer planets like Neptune's Neso:
https://en.wikipedia.org/wiki/Neso(moon) wrote:
<<Neso (for Greek Nereid: Νησώ) is the outermost natural satellite of Neptune. It is an Irregular moon discovered by Holman, Gladman, et al. on August 14, 2002. Neso orbits Neptune at a distance of more than 48 Gm (= 3220 Neptune radii!), making it the most distant known moon of any planet. At apocenter, the satellite is more than 72 Gm from Neptune. This distance is of such an order that it exceeds Mercury's aphelion, which is approximately 70 Gm from the Sun. Neso is also the moon with the longest orbital period, 26.67 years. Neso is about 60 km in diameter based on an assumed albedo.>>
Neptune's Neso:
----------------------------------------------------------
eccentricity: e = 0.5714
semimajor axis: am = 3220 Neptune radii Rp
Neso radius: Rm ~ 30km
---------------------------------------------------------------------------------------
Neso "Hill sphere" radius RH ~ (1 - 0.5714) x 3220 x 30 km = 41,400 km
https://en.wikipedia.org/wiki/Hill_sphere wrote:
<<An astronomical body's
Hill sphere is the region in which it dominates the attraction of satellites. To be retained by a planet, a moon must have an orbit that lies within the planet's Hill sphere.
That moon would, in turn, have a Hill sphere of its own. Any object within that distance would tend to become a satellite of the moon, rather than of the planet itself.
The radius R
H of the Hill sphere for a moon is, approximately equal to (1-e) (where e is the moon's eccentricity) times the moon's semi-major axis a
m divided by the planet's radius (a
m/R
p) times the moon's radius R
m.
Hill sphere radius RH ~ (1-e) x (am/Rp) x Rm
An astronaut could not orbit the Space Shuttle (with mass of 104 tonnes), where the orbit is 300 km above the Earth, because its Hill sphere is only 120 cm in radius, much smaller than the shuttle itself. A sphere of this size and mass would be denser than lead. In fact, in any low Earth orbit, a spherical body must be more dense than lead in order to fit inside its own Hill sphere, or else it will be incapable of supporting an orbit. A spherical geostationary satellite, however, would only need to be more than 6% of the density of water to support satellites of its own.
Within the Solar System, the planet with the largest Hill radius (and thus capable of the most distant moons like Neso) is Neptune, with 116 million km, or 0.775 au; its great distance from the Sun amply compensates for its small mass relative to Jupiter (whose own Hill radius measures 53 million km). An asteroid from the asteroid belt will have a Hill sphere that can reach 220 000 km (for 1 Ceres), diminishing rapidly with decreasing mass. The Hill sphere of
(66391) 1999 KW4, a Mercury-crosser asteroid that has a moon (S/2001 (66391) 1), measures 22 km in radius.
A typical extrasolar "hot Jupiter", HD 209458 b, has a Hill sphere radius of 593,000 km, about 8 times its physical radius of approx 71,000 km. Even the smallest close-in extrasolar planet, CoRoT-7b, still has a Hill sphere radius (61,000 km) six times its physical radius (approx 10,000 km). Therefore, these planets could have small moons close in, although not within their respective Roche limits.>>
[quote="Chris Peterson"][quote="geckzilla"]
I could think of some circumstances that would allow for moons to have moons. There's definitely nothing about physics that makes it impossible once you're at some nth level of of orbiting bodies.[/quote]
Not impossible, no. But whenever you have more than two bodies orbiting, you have an unstable situation. No doubt, planetary moons occasionally capture bodies which become their own moons. But the odds of everything working out so that the resulting orbit is stable over millions of years is very small. So over our narrow temporal window of observation, it's not surprising we don't see them.[/quote]
[c]Any moon tidally locked to it's planet is [b][u]very unlikely[/u][/b]
to have a moon of it's own (in the traditional sense of the word).[/c]
[code]Parent Body Tidally-locked Satellites
---------------------------------------------------------
Earth Moon
Mars Phobos · Deimos
Jupiter Metis · Adrastea · Amalthea · Thebe · Io · Europa · Ganymede · Callisto
Saturn Pan · Atlas · Prometheus · Pandora · Epimetheus · Janus · Mimas
Enceladus · Telesto · Tethys · Calypso · Dione · Rhea · Titan · Iapetus
Uranus Miranda · Ariel · Umbriel · Titania · Oberon
Neptune Proteus · Triton
Pluto Charon [/code]
[c]The most likely moons to have moons in our solar system are those
distantly orbiting small captured asteroids of the outer planets like Neptune's Neso:[/c]
[quote=" https://en.wikipedia.org/wiki/Neso(moon) "]
<<Neso (for Greek Nereid: Νησώ) is the outermost natural satellite of Neptune. It is an Irregular moon discovered by Holman, Gladman, et al. on August 14, 2002. Neso orbits Neptune at a distance of more than 48 Gm (= 3220 Neptune radii!), making it the most distant known moon of any planet. At apocenter, the satellite is more than 72 Gm from Neptune. This distance is of such an order that it exceeds Mercury's aphelion, which is approximately 70 Gm from the Sun. Neso is also the moon with the longest orbital period, 26.67 years. Neso is about 60 km in diameter based on an assumed albedo.>>[/quote]
[c]Neptune's Neso:
----------------------------------------------------------
eccentricity: e = 0.5714
semimajor axis: a[sub]m[/sub] = 3220 Neptune radii R[sub]p[/sub]
Neso radius: R[sub]m[/sub] ~ 30km
---------------------------------------------------------------------------------------
Neso "[b][color=#0000FF]Hill sphere[/color][/b]" radius [b][color=#0000FF]R[sub]H[/sub][/color][/b] ~ (1 - 0.5714) x 3220 x 30 km = 41,400 km[/c]
[quote=" https://en.wikipedia.org/wiki/Hill_sphere"]
<<An astronomical body's [b][color=#0000FF]Hill sphere[/color][/b] is the region in which it dominates the attraction of satellites. To be retained by a planet, a moon must have an orbit that lies within the planet's Hill sphere. [b]That moon would, in turn, have a Hill sphere of its own. Any object within that distance would tend to become a satellite of the moon, rather than of the planet itself.[/b]
The radius R[sub]H[/sub] of the Hill sphere for a moon is, approximately equal to (1-e) (where e is the moon's eccentricity) times the moon's semi-major axis a[sub]m[/sub] divided by the planet's radius (a[sub]m[/sub]/R[sub]p[/sub]) times the moon's radius R[sub]m[/sub].
[c][b][color=#0000FF]Hill sphere[/color][/b] radius [b][color=#0000FF]R[sub]H[/sub][/color][/b] ~ (1-e) x (a[sub]m[/sub]/R[sub]p[/sub]) x R[sub]m[/sub][/c]
An astronaut could not orbit the Space Shuttle (with mass of 104 tonnes), where the orbit is 300 km above the Earth, because its Hill sphere is only 120 cm in radius, much smaller than the shuttle itself. A sphere of this size and mass would be denser than lead. In fact, in any low Earth orbit, a spherical body must be more dense than lead in order to fit inside its own Hill sphere, or else it will be incapable of supporting an orbit. A spherical geostationary satellite, however, would only need to be more than 6% of the density of water to support satellites of its own.
Within the Solar System, the planet with the largest Hill radius (and thus capable of the most distant moons like Neso) is Neptune, with 116 million km, or 0.775 au; its great distance from the Sun amply compensates for its small mass relative to Jupiter (whose own Hill radius measures 53 million km). An asteroid from the asteroid belt will have a Hill sphere that can reach 220 000 km (for 1 Ceres), diminishing rapidly with decreasing mass. The Hill sphere of [url=https://en.wikipedia.org/wiki/(66391)_1999_KW4](66391) 1999 KW4[/url], a Mercury-crosser asteroid that has a moon (S/2001 (66391) 1), measures 22 km in radius.
A typical extrasolar "hot Jupiter", HD 209458 b, has a Hill sphere radius of 593,000 km, about 8 times its physical radius of approx 71,000 km. Even the smallest close-in extrasolar planet, CoRoT-7b, still has a Hill sphere radius (61,000 km) six times its physical radius (approx 10,000 km). Therefore, these planets could have small moons close in, although not within their respective Roche limits.>>[/quote]