Variation of g with altitude and depth

AI Thread Summary
The discussion focuses on the variation of gravitational acceleration (g) with altitude and depth, as described by the equations gh = g(1 - 2h/R) for altitude and gd = g(1 - d/R) for depth, where R is Earth's radius. It is established that g decreases with increasing altitude and depth due to the reduction in the effective mass beneath a point of measurement. At altitude, the distance from Earth's center increases, while at depth, the mass of Earth below diminishes. The mathematical interpretation shows that as the variables h and d increase, the terms subtracted from g also increase, leading to a decrease in g. Understanding these concepts clarifies why gravitational acceleration diminishes both above and below the Earth's surface.
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1. Homework Statement [/
The value of acceleration due to gravity (g) at an altitude (h) is gh = g (1 - 2h/R).
Similarly the value of g at a depth (d) is gd = g(1 - d/R), where R is the radius of the earth.

Homework Equations



In both the cases, my book says the value of g decreases with increase in altitude and increase in depth, by quoting these equations. I don't know how to interpret this result by mere equations. Revered members can help in this regard

The Attempt at a Solution


 
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logearav said:
1. Homework Statement [/
The value of acceleration due to gravity (g) at an altitude (h) is gh = g (1 - 2h/R).
Similarly the value of g at a depth (d) is gd = g(1 - d/R), where R is the radius of the earth.

Homework Equations



In both the cases, my book says the value of g decreases with increase in altitude and increase in depth, by quoting these equations. I don't know how to interpret this result by mere equations. Revered members can help in this regard


The gravitation of attraction of a spherical object is equal to the case when ALL the material "under you feet" is completely concentrated at the center. So just imagine the part of the Earth which is closer to the center than you are, completely collapse to the center.

When you are above Earth's surface (at attitude), the amount of material "under your feet" do not change: it consists of the whole earth, but you are moving further away, you are moving further away from the center (where they "collapsed").

When you are below Earth's surface (at depth), the amount of material "under your feet" is only a portion of the whole earth, and the portion gets smaller as you get closer to the center. So gravity also gets weaker.
 
Sir, i can't understand. Also i want to know how can we say the value of g is deceasing by the given mathematical equations. Thanks for the reply sir
 
The "universal law of gravity" is F= -(GmM)/r^2 where G is the "universal gravitational constant" (NOT "g") , m and M are the masses of the two attracting bodies and r is the distance between the centers of the two bodies. In particular, if we take M to be the mass of the Earth and R to be the radius of the earth, F= -(GM/R^2)m= -gm so that g= GM/R^2. If r= R+ h, then we have F= -GmM/(R+ h)^2.

We can, using the "generalized binomial formula", write (R+h)^{-2}= R^{-2}- 2R^{-3}h+ higher order terms in h so if h is small compared to R, we can approximate -GmM/(R+ h)^2 by -GmM(R^{-2}- 2R^{-3}h= -GmM/R^2+ 2[GmM/R^{-2}](h/R)= -g(1- 2h/R).<br /> <br /> <br /> And, of course, both of the formulas have g(1 <b>minus</b> something) so as that &quot;something&quot; increases, g decreases.
 
Thanks for the reply HallsofIvy.
 

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