On Earth, 90 kg of mass weighs 882 newtons (198.4 pounds).
The weight of an object is calculated using the formula ( \text{Weight} = \text{mass} \times \text{gravity} ). For a 60 kg astronaut on Earth, where the acceleration due to gravity is approximately ( 9.81 , \text{m/s}^2 ), the weight would be ( 60 , \text{kg} \times 9.81 , \text{m/s}^2 = 588.6 , \text{N} ). Therefore, the astronaut weighs about 588.6 newtons on Earth.
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.
On Ganymede, which is a moon of Jupiter, the acceleration due to gravity is about 1.428 m/s^2. To find the weight of the astronaut's spacesuit on Ganymede, you would multiply the mass of the astronaut by the acceleration due to gravity on Ganymede. Therefore, the weight of the astronaut's 900kg spacesuit on Ganymede would be about 1286 N.
The weight of an object is the force of gravity acting on it. On Earth, the weight of a 50kg astronaut would be approximately 490N (using the formula weight = mass x gravity, where gravity on Earth is 9.8 m/s^2).
The question is ill-posed. Weight is mesured in Newtons (N) as it's a force, it's mass is measured in kg. There are ctually two questions mixed together here. Let's answer both: 1) If an astronaut has a mass of 100kg on earth what is his mass on the moon? 100kg - put him on a frictionless surface and try and accelerate him, it's just has hard on the moon as on earth (or anywhere else for that matter). 2) If an astronaut weighs 981N on the surface of the earth (as an astronaut of mass 100kg would) how much does he weigh on the moon? Surface gravity on the earth is 9.81m/s/s which is how we end up with the 100kg astronaut weighing 981N. On the moon surface gravity is only 1.62m/s/s so the same astronaut would weigh 162N - about 1 sixth that on earth.
About 700N 70kg • 10m/s = 700N
A student with a mass of 90 kg on the earth (gravity =9.8m/s/s) will have a weight of 882 Newtons. Weight = Mass * Gravity
A mass of 90 kg weighs 882 newtons (198.4 pounds) on the earth. (rounded)
Using the inverse square law, we can set up the proportion (Weight at initial distance)/(Weight at final distance) = (Final distance^2)/(Initial distance^2). Plugging in the values, we get (90 kg)/W = (6400 km)^2/(7025 km)^2. Solving for W, the astronaut will weigh approximately 102.86 kg when 625 km above the earth.
The weight of Earth is approximately 5.972 × 10^24 kg, and the weight of Venus is roughly 4.867 × 10^24 kg. Therefore, the weight of Earth is greater than the weight of Venus by approximately 1.105 × 10^24 kg.
The average a b and c is 70 kg but the weight of a and b is 90 kg what is the weight of c?data insuffici ent dude
On Ganymede, which is a moon of Jupiter, the acceleration due to gravity is about 1.428 m/s^2. To find the weight of the astronaut's spacesuit on Ganymede, you would multiply the mass of the astronaut by the acceleration due to gravity on Ganymede. Therefore, the weight of the astronaut's 900kg spacesuit on Ganymede would be about 1286 N.
43.10 newtons because weight affect newtons
The weight of an object is the force of gravity acting on it. On Earth, the weight of a 50kg astronaut would be approximately 490N (using the formula weight = mass x gravity, where gravity on Earth is 9.8 m/s^2).
The mass of an astronaut would remain constant, so it would be 80 kg regardless of the planet they are on. Weight, on the other hand, is the force due to gravity acting on the mass of the astronaut, so it would vary depending on the gravitational pull of the planet.
The gravitational pull of Venus is 90% that of the Earth. This means 100 kg on Earth will equal 90 kg on Venus.
Ah, let's paint a happy little picture with numbers, shall we? If a chair has a mass of 90 kilograms, we can find its weight by multiplying the mass by the acceleration due to gravity, which is about 9.8 meters per second squared. So, the weight of the chair would be around 882 Newtons. Just a gentle reminder that every object, no matter how heavy, has its place in this beautiful world.