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Calculating weight on different planets


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I weigh 80kg here on earth.

 

Suppose I travel to a planet that is twice the size of earth, and twice the mass. Assuming an honest scale, what would I weigh on this planet? The knee-jerk response of 160kg is almost certainly wrong — that would make sense if the planet were earth-sized but still twice the mass.

 

But if we start from there and use Newton's (or is it Hookes' ?) inverse square law, then for a planet twice the size, twice the mass of earth wouldn't the scale read (½)² = ¼th of 160kg, or 40kg? Intuitively, that doesn't make much sense. I understand the universe is under no obligation to satisfy my intuition, but am I even right in my calculations?

 

 

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Use [math]g = \frac{-GM}{r^2}[/math] to calculate the surface gravity of the planet you care about. Then just compare that to Earth Norm (~[math]9.8 m/s^2[/math])

 

Edit: Had to remind myself how to do Latex. Been gone a while.

 

Edit 2: Looking at your numbers, the 40kg seems right, if I'm doing the math right (albeit, I'm doing it in my head, so I may be off by any number of orders of magnitude).

 

Edit 3: Actually, kg is a measure of mass, not weight, and your mass wouldn't change. Your weight (in Newtons) would change by 1/2.

 

On Earth, you weigh [math] 80 kg \times 9.81 m/s^2 = 784.8 Newtons[/math].

 

On a planet twice the mass & twice the radius of Earth, you should weigh 392.4 Newtons.

Edited by Greg H.
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Thanks, Greg.

 

I'm beginning to think 40kg is right. We were given (twice the radius, twice the mass) as you might find for Kepler-11b in http://kepler.nasa.gov/Mission/discoveries/, so it's a real question.

 

OTOH, if you think about it, if a [earth-like] planet is twice the radius of earth it should have 8 times the mass of earth, leading to an attractive force of 8/4 what you would have on earth, so my 80kg on earth becomes 160kg on this other planet (not Kepler-11b).

 

So the reason I weigh only 40kg on Kepler-11b is that it's about 1/4th the density of earth. It's sort of a "popcorn planet".

 

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Twice the radius and the mass would mean that the planet's density decreases with size. If you take a similar composition and "compactness", hence density, then gravity increases like the radius.

 

Small asteroids and small moons are known to be fluffy, with density well below ice.

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As Enthalpy says, it's the density that matters. You can actually calculate surface gravity based on density using the following:

 

[math]g = \frac{4\pi}{3} Gpr[/math]

 

Where [math]p[/math] is the density of the object at radius [math]r[/math].

 

Since [math] p = \frac{mass}{volume} [/math] you can compute the change in the surface gravity based on the changes in volume and mass of the planet as compared to earth.

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  • 2 weeks later...

As Enthalpy says, it's the density that matters. You can actually calculate surface gravity based on density using the following:

 

[math]g = \frac{4\pi}{3} Gpr[/math]

 

Where [math]p[/math] is the density of the object at radius [math]r[/math].

 

Since [math] p = \frac{mass}{volume} [/math] you can compute the change in the surface gravity based on the changes in volume and mass of the planet as compared to earth.

'Density of the object. . .' What is the effect of moving from the object's surface into an orbit? I assume we just apply the inverse square rule, right?.

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