You'll weigh about 90kg. Weight is the force of attraction between you and the Earth due to gravity. Mathematically, weight = GMm/r^2, where G is the gravitational constant, M is the mass of the Earth, m is your mass, and r is the distance from the center of the Earth to you. Earth has a radius of 3963 miles. When you are on the ISS, your radius from Earth's center is 4183 miles. Working out the math, objects 220 miles above Earth weigh about 90% of what they weigh on the surface.
That said, you and the ISS are in constant free-fall toward Earth with zero relative motion between the two of you. The ISS isn't pushing against you like the surface of the Earth does, so you feel a sensation of weightlessness, despite having weight.
this is a simple maths sum.
all you gotta do is go the weight on earth (75 pounds) X plutos gravity force (0.08) and you get the answer which is 6 pounds.
you would weigh 6 pounds
A person weighing 100 kg (220 lbs) on the earth would weigh the following on other planets. Notice that along with the weight, I've also written how you convert your earth weight to your weight on that planet:
• Mercury
(earth weight) X 0.38
38 kg (84 lbs)
• Venus
(earth weight) X 0.91
91 kg (200 lbs)
• Mars
(earth weight) X 0.38
38 kg (84 lbs)
• Jupiter
(earth weight) X 2.36
236 kg (520 lbs)
• Saturn
(earth weight) X 0.91
91 kg (200 lbs)
• Uranus
(earth weight) X 0.89
89 kg (196 lbs)
• Neptune
(earth weight) X 1.12
112 kg (247 lbs)
• Pluto (not considered a planet, but I'll list the weight anyway)
(earth weight) X 0.06
6 kg (13 lbs) (we're not very sure about Pluto's gravity, so it's safer to put in "give or take 1 kg".
Edit: In fact there is some uncertainty about all of the "gas giants" too.
Also, to be precise, scientists say a mass in kilograms has a weight in " kilograms weight".
The equatorial surface gravity of Jupiter is 2.528g.
This means that the force due to gravity on Jupiter at the equator is 2.528 times larger than that on earth., As such you would weigh 2.528 times as much.
75 x 2.528 = 189.6 pounds.
W=mg
W= 75 x 9.8
W= 735 N
N= newtons
g = gravitational field strength
m = mass
W = weight
First take the weight in Kilograms and multiply it by 0.453. This would give the weight in kilograms. So in this case the answer is 34 kilograms.
The mass in kilograms of an astronaut on the Moon who weighs 165 lbs on Earth is 12.4kg
On Earth, 66 kg of mass weighs 646.8 newtons (145.5 pounds).
A kilogram is a measure of mass, not of weight. If your mass is 75 kg then you will weigh 665 newtons on Venus, compared to 736 newtons on Earth.
You would not weigh 75kg!
On earth, 66kg weighs 647 newtons or 145.5 lbs.
Mass. Weight is different depending on gravity, but mass is always the same. On the Moon an astronaut weighs less, but has the same mass that they have on Earth.
A pound is a unit of mass. Mass is constant throughout the cosmos, so if the astronaut has a MASS of 180 pounds on Earth, it will be the same even in space. But, the astronaut doesn't have a weight of 180 pounds. His MASS is 180 pounds. Weight = mass x gravity. So, in space, his weight is 0 Newtons.
Its two kilograms. :I
66 kilograms is 10.39 stones.
On earth, 66kg weighs 647 newtons or 145.5 lbs.
Nothing, but his weight is 1/6 of his weight on Earth.
About 700N 70kg • 10m/s = 700N
earth, because earth has a greater gravitational pull
In everyday usage, mass is often interchangeably with "weight". Every astronaut is different, just like everybody else.
mass doesnt change but weight does
No. As long as you continued to eat your astronaut food and do your astronaut exercises, your weight would remain constant on the moon. But it would only be about 16% of your weight on Earth. Your mass would be the same on the moon as it is on Earth, and would also not change while you're there.
On Earth, 90 kg of mass weighs 882 newtons (198.4 pounds).
The moon is considerably smaller than the Earth, both in diameter and in mass, and it therefore has a much weaker gravitational field. The weight of an astronaut on the moon is the result of the mass of the astronaut, which is not changed by going to the moon, and the gravitation field of the moon. A weaker gravitational field produces a lower weight.
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)
the sun reflects the light to the astronaut eyes so the astronaut can see the Earth .
Scott Carpenter was the fourth astronaut to orbit the earth.