Work done by a conservative force

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Titan97
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Homework Statement


The potential energy ##U## of a particle of mass 1kg moving in x-y plane obeys the law ##U=3x+4y##. x and y are in meters. If the particle is at rest at (6,8) at time t=0, then find the work done by conservative force on the particle from initial position to the instant when it crosses the x-axis.

Homework Equations


##\vec F=-\frac{\partial U}{\partial x}-\frac{\partial U}{\partial y}-\frac{\partial U}{\partial z}##
(This equation is not taken from any book. I thought the relation between F and U was just like the relation between electric field and potential)

3. The Attempt at a Solution

Using the equation: ##F=-3\hat i-4\hat j##
Since no other forces are acting, the particle will move in the direction of acceleration. I also have to find the x-coordinate when it crosses x-axis. Acceleration is at an angle ##\tan^{-1}\big(\frac{4}{3}\big)## with the horizontal towards the 3rd quadrant. Hence the particle moves along the line ##y=\frac{4}{3}(x-6)+8##.
So the x intercept is 0. Hence the total distance moved by the particle is 10m. And work done is 50J.
Is this correct?
 
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It is. A lot of work done by you. The work done by the field can also be compared to the difference U(6,8) - U(0,0). Could that be a concidence or is there more to that ? :rolleyes:
 
Work done by conservative force is path independent. But I still need to do "work" to find the final position :smile:. Or is there another way to solve the problem without having to find the final position?
 
Why should it always point at (0,0)? Is it because the force is conservative?
 
I don't understand that. Is it because the minimum magnitude of potential energy is at (0,0)? Since a particle tends to reach minimum potential energy. If that's the case, then is it true for ##U=2x^2+1##? Since force points at (0,1).
 
Potential energy is a scalar. It has a value. Vectors have a magnitude. Unfortunately daily language mixes them up.

Lines of constant U are straight lines for ##
U=3x+4y##. Constant U means no force component along that line. The force points perpendicular to those equipotential lines, so once on a line through the origin means following a straight path through the origin if starting from x > 0 and away from the origin when starting from x ##\le## 0.

For ##
U=x^2+1## lines of constant U are straight lines also. The force always points towards the y axis, not at 0,1 !
 
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