It is not. The Sun has much more mass, therefore it has a greater gravitational attraction.
The Sun has more gravitational attraction on Earth than the Moon, despite its farther distance. However, the effect on the tides is less, in the case of the Sun - tidal forces obey an inverse cube law, more or less.
It is not. The Sun has much more mass, therefore it has a greater gravitational attraction.
The Sun has more gravitational attraction on Earth than the Moon, despite its farther distance. However, the effect on the tides is less, in the case of the Sun - tidal forces obey an inverse cube law, more or less.
It is not. The Sun has much more mass, therefore it has a greater gravitational attraction.
The Sun has more gravitational attraction on Earth than the Moon, despite its farther distance. However, the effect on the tides is less, in the case of the Sun - tidal forces obey an inverse cube law, more or less.
It is not. The Sun has much more mass, therefore it has a greater gravitational attraction.
The Sun has more gravitational attraction on Earth than the Moon, despite its farther distance. However, the effect on the tides is less, in the case of the Sun - tidal forces obey an inverse cube law, more or less.
Incorrect. The Moon generates MUCH more tidal force than the Sun does. Even though the Sun is far more massive, the Moon is much CLOSER - and gravity follows an inverse-square law. For a body that is twice as far away, the gravity is one quarter; for a body 3 times further away, the gravitational force is one-NINTH.
It is not. The Sun has much more mass, therefore it has a greater gravitational attraction.
The Sun has more gravitational attraction on Earth than the Moon, despite its farther distance. However, the effect on the tides is less, in the case of the Sun - tidal forces obey an inverse cube law, more or less.
The sun is too far away to influence the tides.
Yes. The Moon must pull on the Earth with an equal and opposite force.
While the sun has greater mass, the moon is much closer, so the effect on earth's tides is much greater.
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Equal forces acting on an object in opposite directions are called balanced forces. If they are on the same line of action, they are called couple forces.
There is a pair of equal gravitational forces between the Earth and every other bit of matter in the universe. The only ones that make any difference over the span of several human lifetimes are the pair between the Earth and sun, and the pair between the Earth and moon. Mutual gravitational forces between the Earth and each of the other major planets are affecting the Earth's orbit, but the effects are so small as to be imperceptible over the course of human civilization, and too slow for prediction.
Only one force: the Sun's gravity. The centrifugal force is sometimes quoted as an opposing force, but it is actually a ficticious force. If there were really two opposing and equal forces, Earth would move in a straight line, not in an elipse.
Gravity is pushing the rock down toward the Earth and your hand is pushing upward in opposite direction but equal to gravity.
No. The international date line is a zig-zag line between the earth's poles. It has no particular connection to the forces of gravity. Gravity behaves exactly the same way at every point on earth. Wherever an object may be, there are equal forces attracting it and the earth toward each other. The forces are proportional to the product of the object's mass and the earth's mass, and inversely proportional to the square of the distance between their centers. Since the earth's diameter at the equator is slightly larger than its diameter through the poles, objects at the poles are slightly closer to the center of the earth, so the mutual gravitational forces are slightly larger there.
Yes. The gravitational forces between the Earth and moon are equal and opposite ...just like the gravitational forces between everytwo objects are.
The gravitational forces between me and the Earth can be called "my weight on Earth" or "Earth's weight on me". They're equal, and the label doesn't matter.
The force that pulls an object toward earth also pulls the earth toward the object. The two forces are equal. Together, we refer to them as the forces of gravity.
Your weight is one of the two mutual gravitational forces that pull the Earth and you toward each other. The two forces are equal. The Earth weighs exactly as much on you as you weigh on the Earth.
Gravity always acts as a pair of forces, not as one single force. The strength of the forces depends on both masses, not just one of them. The forces of gravity attract the diver toward the earth and the earth toward the diver. The forces are equal in both directions. If the diver weighs 150 pounds on earth, then the earth weighs 150 pounds on the diver. The diver accelerates toward the center of the earth with an acceleration equal to (weight)/(diver's mass), and the earth accelerates toward the diver with an acceleration equal to (weight)/(earth's mass). Has that helped, or just confused the issue further ?
The Earth and you are attracted to the centers of each other by a pair of equal gravitational forces. The size of the force attracting you toward the center of the Earth is your "weight" on Earth. The size of the force attracting the Earth toward the center of you is the Earth's "weight" on you. They are equal.
The Earth and you are attracted to the centers of each other by a pair of equal gravitational forces. The size of the force attracting you toward the center of the Earth is your "weight" on Earth. The size of the force attracting the Earth toward the center of you is the Earth's "weight" on you. They are equal.
The Earth and you are attracted to the centers of each other by a pair of equal gravitational forces. The size of the force attracting you toward the center of the Earth is your "weight" on Earth. The size of the force attracting the Earth toward the center of you is the Earth's "weight" on you. They are equal.
The gravitational forces on two objects are equal. You attract the earth with a force equal to your weight. Whatever you weigh on earth, that's exactly how much the earth weighs on you.
The strength of the gravitational forces between the Earth and an object on or near it is called the "weight" of the object. In reality, there are two equal and opposite forces going on. The Earth attracts the object toward it, with a force that is the weight of the object on Earth. At the same time, the object attracts the Earth toward it, with a force that is the weight of the Earth on the object. The forces are equal. When the object is our body, we obsess about the first one. Nobody ever talks about the second one.
There are two forces of gravity between the Earth and you.One of the forces pulls you toward the center of the Earth.We call the size of that force your "weight".The other gravitational force pulls the Earth toward you.Nobody ever talks about that one. But it's there, and it's EQUAL to your weight.Your weight on Earth is equal to the Earth's weight on you !
Answer #1:The ratio of forces acting on 2 charges 1 and 5 can be 11 if you include theother external factors.===============================Answer #2:The forces on each one due to the other one are equal, regardless of thesize of either charge. That is, the ratio of the forces is always 1 to 1 .Just like with gravity. The force you exert on the Earth is exactly the same asthe force the Earth exerts on you. Your weight on Earth and the Earth's weighton you are equal.