Gravity keeps everything orbiting around the Sun.
Planets are kept in elliptical orbits due to the gravitational force acting between the planet and the sun. This force causes the planet to move in a curved path, resulting in an elliptical orbit. The balance between the planet's inertia and the gravitational force determines the shape of the orbit.
the answer is: the elliptical orbit of the planet
The gravatiational pull. They orbit around the sun.
Plants remain in orbit around the sun, like all other objects in the solar system, due to the gravitational force exerted by the sun. This force keeps them moving in a circular or elliptical path around the sun. The balance between the gravitational force of the sun and the plants' inertia keeps them in orbit.
The Earth orbits the Sun due to the gravitational pull between the two objects. This gravitational force keeps the Earth in its elliptical path around the Sun, maintaining its orbit.
The Earth orbits the Sun due to the gravitational pull between the two objects. This gravitational force keeps the Earth in its elliptical path around the Sun, maintaining its orbit.
Saturn spins around the sun in an elliptical orbit due to the gravitational pull of the sun. This orbit is maintained by the balance between the sun's gravity pulling Saturn towards it, and the centrifugal force of Saturn moving forward in its orbit.
An orbit is the circular or elliptical motion of one smaller body around another larger body due to gravitational attraction.
Planets revolve around the sun due to the gravitational force exerted by the sun. This force keeps the planets in orbit as they move through space, following elliptical paths. The balance between the planet's inertia and the sun's gravitational pull determines the planet's orbit around the sun.
Planets orbit the Sun in an elliptical path. This path is determined by the gravitational pull of the Sun on the planet, causing it to move in an elliptical orbit. The orbit is maintained due to a balance between the planet's inertia and the gravitational force of the Sun.
In a complete circular orbit of an electron around a nucleus, the work done by the field of the nucleus is zero. This is because the force is always perpendicular to the direction of motion, so there is no displacement along the direction of the force, resulting in no work done. If the orbit is elliptical, there would be work done by the field of the nucleus due to the non-zero component of the force parallel to the direction of motion during the orbital motion.
Mercury and Pluto have the most elliptical orbits among the planets in our solar system. Mercury's orbit is the most eccentric, while Pluto's orbit is also highly elliptical due to its distance from the Sun and its eccentric orbit.