the cycle of seasons most affects the earth around the sun
The gravitational interaction of the Earth and Moon produces a number of effects. The most obvious of these is the orbital motion of the Moon around the Earth, but there is also a motion of the Earth around the center of mass of the Earth-Moon system, tidal effects on the Earth and Moon and professional effects on the Earth's axis of rotation.
It depends on what effect you mean. The sun affects the weather on Earth the most and the moon affects the tides on Earth the most.
Its mass.
The Sun's gravity holds the solar system together.
Earth. I had the same question on a science packet.
The gravitational interaction of the Earth and Moon produces a number of effects. The most obvious of these is the orbital motion of the Moon around the Earth, but there is also a motion of the Earth around the center of mass of the Earth-Moon system, tidal effects on the Earth and Moon and professional effects on the Earth's axis of rotation.
Migration of animals is usually seasonal and seasons are related to earth motion .Most animals migrate before and after winter to avoid winter .
It depends on what effect you mean. The sun affects the weather on Earth the most and the moon affects the tides on Earth the most.
A force that most affects the path of a planet around the Sun is gravity.
the corona affects the earth the most
Earth.
The water cycle
a washing machine, electrons orbiting in an atom, and the most important is satellites revolving around earth.
Earth's surface is a common reference point for detecting motion.
The layer that affects the earth's surface is ozone. Ozone is a layer of importance.
Earth's surface is a common reference point for determining position and motion.
The most commonly discussed "retrograde" motion is the apparent backward motion of a planet caused by its being lapped by another planet, or vice-versa. Both planets move in a direct (eastward) motion around the Sun, but the planet with the inside (smaller) orbit moves faster than the planet on the outside (larger) orbit, and when it passes the slower-moving planet, each sees the other one as apparently moving backwards relative to its usual motion around the sky. In this "retrograde" motion, neither planet is actually moving backwards; it only appears that way, during the time that one laps the other.