your mass would stay the same (mass never changes), but your weight would be about one sixth (1/6) of what it is one earth
There is gravity on the moon! The gravity on the Moon is 1/6th that of what is observed on Earth. An object with a weight of 36 kg on Earth would weigh 1/6th that on the Moon. 1/6th of 36kg is, 6 kg. An object with a MASS of 36 kg on Earth would have the same 36 kg MASS on the moon. Mass is the amount of matter that makes up an object, whereas WEIGHT is the measurement of the force of gravity on that MASS. This is why your weight will change when visiting other planets, but your mass stays constant plant to planet!
Your weight would change on the moon because gravity is weaker there compared to Earth, so you would feel lighter. However, your mass would remain the same because it is a measure of the amount of matter in your body, which does not change.
If you measured your mass and your weight and then went to the moon, you would find that your mass had not changed, and your weight had become about 83 percent less.
The mass of an object would remain the same on the moon as it is on Earth. Mass is a measure of the amount of matter in an object, so it does not change with location. However, the weight of the object would be less on the moon due to the moon's lower gravity compared to Earth.
The mass of an object remains the same regardless of where it is located, so the object would still have a mass of 120 g on the moon. However, its weight would be different on the moon due to the moon's lower gravity compared to Earth.
There is gravity on the moon! The gravity on the Moon is 1/6th that of what is observed on Earth. An object with a weight of 36 kg on Earth would weigh 1/6th that on the Moon. 1/6th of 36kg is, 6 kg. An object with a MASS of 36 kg on Earth would have the same 36 kg MASS on the moon. Mass is the amount of matter that makes up an object, whereas WEIGHT is the measurement of the force of gravity on that MASS. This is why your weight will change when visiting other planets, but your mass stays constant plant to planet!
* Mass doesn't change because of conservation of mass. * Weight changes because it is the product of mass x gravity - and gravity on the Moon is less.
So if you take your weight then divide it by 6.13 that is your on the moon and your mass stays the same.
Your weight would change on the moon because gravity is weaker there compared to Earth, so you would feel lighter. However, your mass would remain the same because it is a measure of the amount of matter in your body, which does not change.
Your mass will not change, but your weight will.
Such an object's mass would not change, or it wouldn't change significantly. Its weight will be reduced, approximately by a factor of 6.
Your mass would remain the same on the moon as it is a measure of the amount of matter in your body. However, your weight would be about 1/6th of what it is on Earth due to the weaker gravitational pull on the moon.
If you measured your mass and your weight and then went to the moon, you would find that your mass had not changed, and your weight had become about 83 percent less.
No, the weight of the moon rock would not change if it was brought to Earth. Weight is a measure of the force of gravity acting on an object, which would be the same on the moon as it is on Earth. The mass of the rock would stay the same as well.
(Yes. The mass on the moon is 1/81 than it is on Earth.) No I'm sorry but this is incorrect. Mass is a measure of the number of particles you have, i.e how big you are Weight decreases on the moon, as it is a force caused by gravity.
The mass of an object would remain the same on the moon as it is on Earth. Mass is a measure of the amount of matter in an object, so it does not change with location. However, the weight of the object would be less on the moon due to the moon's lower gravity compared to Earth.
A person's mass is the same on the moon as it is on Earth because mass does not change based on location. However, their weight would be about 1/6th of what it is on Earth due to the moon's weaker gravitational pull.