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What is the mass of an astronaut on earth?
The mass of an astronaut on Earth would be the same as their mass in space. Mass is a measure of the amount of matter in an object and does not change with location. It is the weight of the astronaut that would vary depending on the gravitational force acting on them.
Is the mass of the astronaut on Mars bigger smaller or the same compared with on Earth?
You would have the same mass on the Earth as you would on the moon. You would just weigh less on the moon because there is less gravity there than on the moon.
Why does an astronaut still have the same mass on the moon?
Your mass is the amount of matter that contains, it is your weight that will differ due to gravity. The astronaut still has the same amount of matter whether he be on earth, in space, or on the moon, though due to the different strenghts of gravity he will weight the most on earth, 1/6th of this on the moon, and be weightless in outer space.
What is Mass of Astronaut on earth?
The mass of an astronaut on Earth is the same as their mass anywhere else, as mass is a measure of the amount of matter in an object and does not change with location. However, the weight of the astronaut, which is the force exerted by gravity on that mass, varies depending on the gravitational pull of the celestial body they are on. On Earth, an astronaut's weight can be calculated by multiplying their mass by Earth's gravity, approximately 9.81 m/s². For example, an astronaut with a mass of 70 kg would weigh about 686 newtons on Earth.
What is the weight of the astronaut on earth What is the weight of the astronaut on the moon?
The weight of an astronaut on Earth is determined by their mass multiplied by the gravitational acceleration of Earth, which is approximately 9.81 m/s². For example, if an astronaut has a mass of 80 kg, their weight on Earth would be about 784 Newtons (N). On the Moon, the gravitational acceleration is about 1.62 m/s², so the same astronaut would weigh approximately 129.6 N on the Moon. Thus, the astronaut's weight decreases significantly when on the Moon due to the lower gravitational pull.
What is the astronaut inertia on the moon?
The astronaut's inertia on the moon would be the same as on Earth, as inertia is an object's resistance to a change in motion. However, due to the moon's lower gravity, the astronaut would weigh less and experience a reduced force opposing their motion compared to Earth.
What has changed to cause the weight of the astronaut to be different?
weight= mass*gravity in this case, an astronauts mass has stayed the same, but the gravitational force acting upon him has decreased, decreasing his weight. gravity decreses because the astronaut is further from the centre of gravitational attraction (the earth)
How are bricks and bananas alike How are they different?
they are not the same nothings the same and but if the banana is moldy it gets hard
An astronaut on the moon would have the same as on Earth?
An astronaut on the moon would experiences one-sixth (16.5%) the gravity that they do on Earth. This means that they would weigh less and have less resistance to movement.
Is it he does not like bananas or apples or bananas and apples?
Both are right but the meanings are different. 'He does not like bananas or apples' asserts two things: 'He does not like bananas'; 'He does not like apples.' He does not like bananas and apples means that he does not like bananas and apples together (eaten at the same time).
What happens to the mass of an astronaut when he is on the moon?
The mass of an astronaut remains the same on the moon as it does on Earth. Mass is a measure of the amount of matter in an object and does not change based on location. However, the astronaut's weight would be less on the moon due to the moon's lower gravitational force compared to Earth.
Triple earth's mass effect its orbit?
The earth's mass has no effect on its orbit. An astronaut on a "space walk" hovering over the space shuttle's cargo bay is in the same earth-orbit as the shuttle itself is, although his mass is much less than the shuttle's mass. At the same time, the shuttle and the astronaut are both in the same solar orbit as the earth is, although each of them has quite a bit less mass than the earth has.
