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6.2: Forces and Potential Energy

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    22233
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    In the last chapter I mentioned a special case that we encounter often, in which a lighter object is interacting with a much more massive one, so that the massive one essentially does not move at all as a result of the interaction. Note that this does not contradict Newton’s 3rd law, Equation (6.1.5): the forces the two objects exert on each other are the same in magnitude, but the acceleration of each object is inversely proportional to its mass, so \(F_{12} = −F_{21}\) implies

    \[ m_{2} a_{2}=-m_{1} a_{1} \label{eq:6.12} \]

    and so if, for instance, \(m_{2} \gg m_{1}\), we get \(\left|a_{2}\right|=\left|a_{1}\right| m_{1} / m_{2} \ll\left|a_{1}\right|\). In words, the more massive object is less responsive than the less massive one to a force of the same magnitude. This is just how we came up with the concept of inertial mass in the first place!

    Anyway, you’ll recall that in this situation I could just write the potential energy function of the whole system as a function of only the lighter object’s coordinate, \(U(x)\). I am going to use this simplified setup to show you a very interesting relationship between potential energies and forces. Suppose this is a closed system in which no dissipation of energy is taking place. Then the total mechanical energy is a constant:

    \[ E_{\text {mech}}=\frac{1}{2} m v^{2}+U(x)=\text { constant } \label{eq:6.13} \]

    (Here, \(m\) is the mass of the lighter object, and \(v\) its velocity; the more massive object does not contribute to the total kinetic energy, since it does not move!)

    As the lighter object moves, both \(x\) and \(v\) in Equation (\ref{eq:6.13}) change with time (recall, for instance, our study of “energy landscapes” in the previous chapter, section 5.1). So I can take the derivative of Equation (\ref{eq:6.13}) with respect to time, using the chain rule, and noting that, since the whole thing is a constant, the total value of the derivative must be zero:

    \begin{align}
    0 &=\frac{d}{d t}\left(\frac{1}{2} m(v(t))^{2}+U(x(t))\right) \nonumber \\
    &=m v(t) \frac{d v}{d t}+\frac{d U}{d x} \frac{d x}{d t} \label{eq:6.14}.
    \end{align}

    But note that \(dx/dt\) is just the same as \(v(t)\). So I can cancel that on both terms, and then I am left with

    \[ m \frac{d v}{d t}=-\frac{d U}{d x} \label{eq:6.15} .\]

    But \(dv/dt\) is just the acceleration \(a\), and \(F = ma\). So this tells me that

    \[ F=-\frac{d U}{d x} \label{eq:6.16} \]

    and this is how you can always get the force from a potential energy function.

    Let us check it right away for the force of gravity: we know that \(U^G = mgy\), so

    \[ F^{G}=-\frac{d U^{G}}{d y}=-\frac{d}{d y}(m g y)=-m g \label{eq:6.17} .\]

    Is this right? It seems to be! Recall all objects fall with the same acceleration, −\(g\) (assuming the upwards direction to be positive), so if \(F = ma\), we must have \(F^G = −mg\). So the gravitational force exerted by the earth on any object (which I would denote in full by \(F^G_{E,o}\)) is proportional to the inertial mass of the object—in fact, it is what we call the object’s weight—but since to get the acceleration you have to divide the force by the inertial mass, that cancels out, and \(a\) ends up being the same for all objects, regardless of how heavy they are.

    Now that we have this result under our belt, we can move on to the slightly more challenging case of two objects of comparable masses interacting through a potential energy function that must be, as I pointed out in the previous chapter, a function of just the relative coordinate \(x_{12} = x_2 − x_1\).

    I claim that in that case you can again get the force on object 1, \(F_{21}\), by taking the derivative of \(U(x_2 − x_1)\) with respect to \(x_1\) (leaving \(x_2\) alone), and reciprocally, you get \(F_{12}\) by taking the derivative of \(U(x_2 − x_1)\) with respect to \(x_2\). Here is how it works, again using the chain rule:

    \begin{align}
    &F_{21}=-\frac{d}{d x_{1}} U\left(x_{12}\right)=-\frac{d U}{d x_{12}} \frac{d}{d x_{1}}\left(x_{2}-x_{1}\right)=\frac{d U}{d x_{12}} \nonumber \\
    &F_{12}=-\frac{d}{d x_{2}} U\left(x_{12}\right)=-\frac{d U}{d x_{12}} \frac{d}{d x_{2}}\left(x_{2}-x_{1}\right)=-\frac{d U}{d x_{12}} \label{eq:6.18}
    \end{align}

    and you can see that this automatically ensures that \(F_{21} = −F_{12}\). In fact, it was in order to ensure this that I required that \(U\) should depend only on the difference of \(x_1\) and \(x_2\), rather than on each one separately. Since we got the condition \(F_{21} = −F_{12}\) originally from conservation of momentum, you can see now how the two things are related1.

    The only example we have seen so far of this kind of potential energy function was in last chapter’s Section 5.1, for two carts interacting through an “ideal” spring. I told you there that the potential energy of the system could be written as \(\frac{1}{2} k(x_2 − x_1 − x_0)^2\), where \(k\) was the “spring constant” and \(x_0\) the relaxed length of the spring. If you apply Eqs. (\ref{eq:6.18}) to this function, you will find that the force exerted (through the spring) by cart 2 on cart 1 is

    \[ F_{21}=k\left(x_{2}-x_{1}-x_{0}\right) \label{eq:6.19} .\]

    Note that this force will be negative under the assumptions we made last chapter, namely, that cart 2 is on the right, cart 1 on the left, and the spring is compressed, so that \(x_2 − x_1 < x_0\). Similarly,

    \[ F_{12}=-k\left(x_{2}-x_{1}-x_{0}\right) \label{eq:6.20} \]

    and this one, as it should, is positive.

    The results (\ref{eq:6.19}) and (\ref{eq:6.20}) basically tell you what we mean by an “ideal spring” in physics: it is a spring that pulls (if stretched) or pushes (if compressed) with a force that is proportional to the change from its equilibrium length. Thus, if you fasten one end of the spring at \(x\) = 0, and stretch it or compress it so that the other end is at \(x\), the spring will respond by exerting a force

    \[ F^{s p r}=-k\left(x-x_{0}\right) \label{eq:6.21} .\]

    As you can see, this is negative if \(x > x_0 > 0\) (spring stretched, pulling force) and positive if \(x < x_0\) (spring compressed, pushing force). In fact, the spring exerts an equal (in magnitude) and opposite (in direction) force at the other end (the one attached to the wall), so Equation (\ref{eq:6.21}) only gives the correct sign of the force at the end that is denoted by the coordinate value \(x\). Equations (\ref{eq:6.19}) and (\ref{eq:6.20}) are a bit clearer in this respect: Equation (\ref{eq:6.19}) gives the correct sign of the force at point \(x_1\), and Equation (\ref{eq:6.20}) the correct sign at point \(x_2\).

    Figure \(\PageIndex{1}\) shows, in black, all the forces exerted by a spring with one fixed end, according as to whether it is relaxed, compressed, or stretched. I have assumed that it is pushed or pulled by a hand (not shown) at the “free” end, hence the subscript “\(h\)”, whereas the subscript “\(w\)” stands for “wall.” Note that the wall and the hand, in turn, exert equal and opposite forces on the spring, shown in red in the figure.

    Figure6-2-1.png
    Figure \(\PageIndex{1}\): Forces (in black) exerted by a spring with one end attached to a wall and the other pushed or pulled by a hand (not shown). In every case the force is proportional to the change in the length of the spring from its equilibrium, or relaxed, value, shown here as \(x_0\). For this figure I have set the proportionality constant \(k\) = 1. The forces exerted on the spring, by the wall and by the hand, are shown in red.

    Equation (\ref{eq:6.21}) is generally referred to as Hooke’s law, after the British scientist Robert Hooke (a contemporary of Newton). Of course, it is not a “law” at all, merely a useful approximation to the way most springs behave as long as you do not stretch them or compress them too much2.

    A note on the way the forces have been labeled in Figure \(\PageIndex{1}\). I have used the generic symbol “\(c\)”, which stands for “contact,” to indicate the type of force exerted by the wall and the hand on the spring. In fact, since each pair of forces (by the hand on the spring and by the spring on the hand, for instance), at the point of contact, arises from one and the same interaction, I should have used the same “type” notation for both, but it is widespread practice to use a superscript like “spr” to denote a force whose origin is, ultimately, a spring’s elasticity. This does not change the fact that the spring force, at the point where it is applied, is indeed a contact force.

    So, next, a word on “contact” forces. Basically, what we mean by that is forces that arise where objects “touch,” and we mean this by opposition to what are called instead “field” forces (such as gravity, or magnetic or electrostatic forces) which “act at a distance.” The distinction is actually only meaningful at the macroscopic level, since at the microscopic level objects never really touch, and all forces are field forces, it is just that some are “long range” and some are “short range.” For our purposes, really, the word “contact” will just be a convenient, catch-all sort of moniker that we will use to label the force vectors when nothing more specific will do.


    1The result (\ref{eq:6.18}) generalizes to more dimensions, but to do it properly you need vectors and partial derivative notation, and I’m already bending the notational rules a little bit here..

    2Assuming that you can compress them! Some springs, such as slinkies, actually cannot be compressed because their coils are already in contact when they are relaxed. Nevertheless, Equation (\ref{eq:6.21}) will still apply approximately to such a spring when it is stretched, that is, when \(x>x_0\).


    This page titled 6.2: Forces and Potential Energy is shared under a CC BY-SA 4.0 license and was authored, remixed, and/or curated by Julio Gea-Banacloche (University of Arkansas Libraries) via source content that was edited to the style and standards of the LibreTexts platform; a detailed edit history is available upon request.

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