Qns on potential energy and forces

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SUMMARY

The potential energy of a body at point P, a distance x from reference point O, is defined by the equation V = kx², where k is a constant. The correct force acting on the body at point P is determined to be 2kx directed towards point O. This conclusion arises from the relationship between work and force, where the force is derived from the negative gradient of potential energy, leading to the formula F = -dW/dx. The discussion clarifies the importance of understanding variable forces and the significance of reference points in potential energy calculations.

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Hello, i hope i posted this in the correct section..

I have a question:
the potential energy of a body when it is at point P a distance x from a reference point O is given by V = kx^2, where k is a constant. what is the force acting on the body when it is at P?

the correct ans is 2kx in the direction of PO

the ans i got is kx in the direction OP. as work = force x distance, so force required to bring the body to point p is kx^2 / x .

could some please explain why is the correct ans so? thnk u so much!
 
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Work is "force times distance" as long as the force is constant- if the force is a variable then the work is given by \int f(x)dx. Notice that this involves a "constant of integration". It is standard to choose that constant so that potential energy is 0 at some specific point; potential energy is always relative to some given point.

Going the other way, if work is a constant times distance, W= Cx then force is that constant: F= Cx/x= C. But if a more general function then F= \frac{dW}{dx}.
 
The potential energy is positive. So there is an attraction toward the origin.

The force = - (dW/dx) = -2kx.
So the force is directed from the point P to the point O, the origin.
bye
 
Thnx a lot!
 

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