The problem involves determining the distance from Earth at which the gravitational pull of the Moon on a spaceship exceeds that of the Earth. The context is rooted in gravitational forces and involves calculations based on the masses of the Earth and Moon, as well as their distance apart.
Some participants have provided guidance on verifying calculations and checking the reasonableness of results. There is an ongoing exploration of the mathematical steps involved, with some questioning the accuracy of the original poster's approach and suggesting corrections to the algebraic manipulations.
Participants note the importance of using accurate values for gravitational acceleration and the relevance of the distance between the Earth and the Moon. There is also mention of the original poster's upcoming exam, which adds a sense of urgency to the discussion.
Jokerhelper said:you should always do a check to see if your answer is reasonable. According to your answer, once the distance from the Earth is greater than 3.82 x 108 m, the gravitational pull of the Moon will be greater than the Earth's pull. In this case, what would be a good way to verify your answer?
no no no. let's get somethings straight. The gravity of a planet is always related to the distance of the object to such planet.mlostrac said:Hmmm. I know the force of gravity on the moon is 17% of that on Earth (9.8 m/s^2 versus 1.66 m/s^2). I'm not exactly sure how to check my answer though...
Do I use Mss x g = G (Mss x Me)/ R^2 --> and calculate to find R for each (the spaceship from the Moon and the spaceship from the earth)?
:s
Jokerhelper said:no no no. let's get somethings straight. The gravity of a planet is always related to the distance of the object to such planet.
For example, have you ever wondered why you often use in high school 2 formulae to calculate the gravitational force of the Earth?
F_{g} = mg and also F_{g} = G\frac{mM_{e}}{r^{2}}
Therefore, g = \frac{GM_{e}}{r^{2}}, for the Earth's gravity. This is also applicable for any planet or object with mass. Note that the values of 9.81 m/s2 for the Earth and 1.66 m/s2 for the moon are true only at the surfaces of the respective bodies, where the radius is fixed. Hence, you cannot using those values to verify if your answer is correct.
By the way, according to your answer G\frac{M_{e}M_{ss}}{R^{2}} = G\frac{M_{m}M_{ss}}{(z-R)^{2}} when R = 3.82x102 . Maybe you could plug in your known values to verify if this is true.
mlostrac said:I got 3.82 x 10^8 m (the distance from the Earth to the spaceship) using my numbers. So am I wrong? I'm assuming the Earth will have a greater pull than the moon, so this answer seems like it makes sense in that respect. But I'm not sure if I did everything correctly? My exam's tonight (Friday), and I'd like to figure this out before then.
Thanks for your help
Jokerhelper said:woops, i meant to copy your answer 3.82 x10^8 m (not 10^2), which i think might be incorrect. your approach is correct, but I think you might have made a mistake while expanding (z-R)^2.
Remember (a+b)^2 = a^2 + 2ab + b^2.
Actually, I'll post what you should have done, since your exam is tomorrow and, as a student myself, i can relate to how it feels to not be able to solve a question right before an exam. Just give me a few minutes to work it out.
no. (z-R)^2 =/= (z-R) (z+R)mlostrac said:wouldn't (z-R)^2 be (z-R) (z+R) = z^2 -zR+zR -R^2 therefore equaling z^2 - R^2 ? That's what I did originally