Wiki User
∙ 13y agoYes. Mass is intrinsic to objects wherever they are. Weight and momentum can change with position.
Wiki User
∙ 13y agoYes. Mass is a measure of the amount of matter in an object and remains constant regardless of the location. Weight, on the other hand, is the force of gravity acting on an object and can differ depending on the gravitational strength of the location.
No, the mass density of an object would not be the same on the moon as on Earth. The mass of the object would remain the same, but since the gravitational pull on the moon is weaker than that on Earth, the volume of the object would decrease on the moon, resulting in a different mass density calculation compared to Earth.
The mass of an object will remain the same regardless of its location. So, the mass of an object that is 60 units on Earth will also be 60 units on the moon.
The mass of the object remains the same on the moon as it is on Earth. However, the weight of the object will be approximately 1/6th of its weight on Earth due to the moon's lower gravity.
The object's mass doesn't change, no matter where it is or where it goes.
The mass of an object remains the same regardless of its location because mass is a measure of the amount of matter in an object, which does not change. Gravity affects the weight of an object, not its mass, so an object will have the same mass on the Moon as it does on Earth, but it will weigh less on the Moon due to the Moon's lower gravitational pull.
No, the mass density of an object would not be the same on the moon as on Earth. The mass of the object would remain the same, but since the gravitational pull on the moon is weaker than that on Earth, the volume of the object would decrease on the moon, resulting in a different mass density calculation compared to Earth.
The mass of an object will remain the same regardless of its location. So, the mass of an object that is 60 units on Earth will also be 60 units on the moon.
there is no change in the mass of body
The mass of the object remains the same on the moon as it is on Earth. However, the weight of the object will be approximately 1/6th of its weight on Earth due to the moon's lower gravity.
The object's mass doesn't change, no matter where it is or where it goes.
The 10N object has the same mass whether on the moon or on Earth. Mass is an intrinsic property of an object that does not change with location. However, the weight of the object would be lower on the moon due to the moon's weaker gravity compared to Earth.
Yes, but the weight of that mass will be different.
The mass of an object remains the same regardless of its location because mass is a measure of the amount of matter in an object, which does not change. Gravity affects the weight of an object, not its mass, so an object will have the same mass on the Moon as it does on Earth, but it will weigh less on the Moon due to the Moon's lower gravitational pull.
The mass of the object remains the same on the moon as it is on Earth, so it would still be 20kg. Mass is a measure of the amount of matter in an object and is independent of the gravitational pull of the environment.
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 its location. Mass is a measure of the amount of matter in an object, so it does not change when the object is moved from Earth to the Moon. However, the object's weight would change due to the difference in gravitational pull between Earth and the Moon.
The amount of matter an object has, also known as its mass, would remain the same whether the object is on the moon or on Earth. Mass is an intrinsic property of an object and is independent of the object's location. However, the object's weight (the force of gravity acting on it) would be different on the moon compared to Earth due to the moon's lower gravity.