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Yes, density is defined as mass divided by volume, and mass doesn't change when you take something on a spaceship.
Yes, density is defined as mass divided by volume, and mass doesn't change when you take something on a spaceship.
Yes, density is defined as mass divided by volume, and mass doesn't change when you take something on a spaceship.
Yes, density is defined as mass divided by volume, and mass doesn't change when you take something on a spaceship.
What else can I help you with?
What is the density of a steel hammer on a spaceship?
The density is not affected by gravity. it is a measure of a substances mass to volumn. Therefor the density of a steel hammer on a spaceship is the same as one on earth (approx 7850 kg/m^3)
Would an object have the same mass density on the moon as it does on earth?
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.
Is the density of an object the same in outer space as on earth?
Yes
If the denity of a steal hammer is 7.6 gcm3 on earth how much density would it have on a spaceship?
The density of the hammer is the same no matter where it is. Density = Mass / volume. Neither Mass nor volume is dependent on gravity there for Density is also independent of gravity.
The Moon's average density is about the same as the density of which of the Earth's layers?
The moon's average density is about the same as the density of mantle of the Earth.
The weight of a spaceship of the moon would be less than it is on earth but which measurements would remain the same?
While the weight of a spaceship on the Moon is less due to the Moon's weaker gravitational pull, its mass remains the same regardless of location. Mass is a measure of the amount of matter in the spaceship and does not change whether it's on Earth, the Moon, or in space. Additionally, other properties such as volume and density would also remain constant.
Is the centre of gravity the same for an object placed on the moon and the surface of the earth?
Yes. COG is determined by the object shape & density distribution, not by its location.
Do you weigh less on Earth than in a spaceship orbiting 800 km above Earth?
No, you actually weigh slightly less in a spaceship orbiting 800 km above Earth compared to your weight on the surface of Earth. This is because weight is the force of gravity acting on an object, and gravitational force decreases with distance from the Earth's center. In orbit, you experience microgravity, which gives the sensation of weightlessness, but your mass remains the same. Thus, while you still have weight in a spaceship, it is less than what it would be on Earth's surface.
If you are on a spaceship would the density of a 7.9 g per square cm have a density of 0 g per square cm?
no, the mass would stay the same and the volume would stay the same so density is also the same
Do you weigh less on earth than in a spaceship orbiting 800 kilometers above earth?
Yes, you weigh less in a spaceship orbiting 800 kilometers above Earth compared to your weight on the Earth's surface. This is because weight is the force of gravity acting on an object, and gravitational force decreases with distance from the Earth's center. In orbit, you experience microgravity due to the continuous free-fall motion of the spaceship and its occupants, making you feel lighter. However, your mass remains the same in both locations.
What is the density of a big object vs the smaller object of the same material?
The density of both objects will be the same regardless of their size if they are made of the same material. Density is a physical property of a material that remains constant regardless of the object's size or shape.
What will happen to an object if the density of that object cut in half?
If the density of an object is cut in half, the object's mass remains the same but its volume doubles. This means the object will become larger in size but will still have the same mass.
