Yes. That's what determines the shape and size of ALL orbits.
They can orbit Uranus because of its gravitational force.
Because of the tides which are controlled by the moons orbit and gravitational force
time and an orbit
Planets and their moons stay in orbit due to the balance between the gravitational pull of the planet and the moon's motion. This balance is governed by Newton's law of universal gravitation. As long as the gravitational force between the planet and its moon is strong enough to keep the moon in orbit, they will continue to move in a stable path.
The moons stay in orbit around Jupiter due to the planet's strong gravitational pull. This gravitational force keeps the moons in check and prevents them from moving away into space. They orbit around Jupiter because of the balance between their inertia and the gravitational force pulling them towards the planet.
Gravity is the force that holds planets and moons in orbit around larger celestial bodies, such as stars or planets. The gravitational pull between these objects creates a balance between the centrifugal force of their motion and the gravitational force pulling them towards each other, resulting in stable orbits.
Gravity is the force that keeps planets and moons in orbit. The gravitational pull between the planet or moon and the object they are orbiting around, typically a star like the sun, is what keeps them moving in a stable path. This balance between the gravitational force and the object's inertia causes them to continuously orbit in a closed path.
Moons orbit around planets. They are natural satellites that are held in orbit by the planet's gravitational pull.
the gravitational pull of a star, which is made up of matter, which makes up everything...
Gravity. As the planet rotates it's mass holds it's moons within it's orbit. The larger the planet the stronger is its gravitational pull.
The Earth's gravitation force is greater than the Moon, which keeps the Moon in orbit round the Earth.
Because Earth and all the other planets and moons have a gravitational pull. This pull is distributed so that everthing stays in orbit.