What is the relationship between work and potential energy?

AI Thread Summary
The discussion explores the relationship between work and potential energy, specifically addressing the confusion around the equations ΔU = W and W = U2 - U1. It clarifies that the negative sign in the first equation indicates that work done against gravity results in a decrease in potential energy. The example of launching a satellite illustrates that an external force, such as a rocket booster, performs work against gravitational force, which is why the equations appear different. Both scenarios—lifting an object by hand or using a rocket—ultimately relate to the change in total mechanical energy, combining potential and kinetic energy. Understanding these concepts is crucial for grasping the principles of physics before formal study.
soljaragz
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Hi, I haven't taken physics yet, but I am reading a Sparknotes Physics book for fun, and there's something that i don't understand

In one part of the book, when it was talking about basic energy stuff it said that - ΔU = W

http://www.sparknotes.com/physics/workenergypower/conservationofenergy/terms.html

but then a few chapters later it shows a problem with potential gravitational energy, and

it said "W= U2 - U1" ... what happened to the negative sign?


(no source, since the website on this chapter is not current)
 
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Probably the later reference has some outside agent (a person?)
doing Work against the gravitational Force.
If the motion is always slow, then the person's Force is opposite gravity's
(that is, F by person = NEGATIVE F by gravity).

So that Energy is *transferred* as the Force application point is moved.
 
Last edited:
Hmm...im not sure

but here is the actual problem

A satellite of mass m is launched from the surface of the Earth into an orbit of radius 2r, where r is the radius of the Earth. How much work is done to get it into orbit?
 
W = U2-U1 = -G(m1m2)/2r - -Gm1m2/r

in the book it said potential grav. energy is -G(m1m2)/r where r is displacement and m1 is object mass, m2 is Earth mass
 
It takes an "outside agent" (a rocket booster!) that does Work
to get the satellite into orbit ...
gravity's Force removes Energy from the satellite as the satellite rises.

By the way, Grav.P.E. is negative, which reminds us that we are trapped
down here ... we need to add Energy to something just to get it far away,
and additional Energy to make it go fast there.
 
hmmm..ok i sort of get it
 
I guess I should have said (in post #2) that

The Work done by gravity's Force = - Delta U = - Ufinal - Uinitial .

To lift something, your Force apllied to that thing
is (approx) the negative of gravity's Force applied to it.
 
you mean -DeltaU = -(Ufinal - U).

but what is the difference between a hand picking up an object against gravity, and a rocketbooster boosting a rocket against gravity?
shouldn't they be using the same formula?
but what I am seeing is the first problem uses W=-DeltaU and the latter uses W=DeltaU...

ugh, I can't wait to take physics next year
 
In both cases the work done by the outside force--hand or rocket--will equal the change in total mechanical energy (PE + KE).
 

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