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7.15: Conservative and Non-Conservative Forces

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    Learning Objectives
    • Characterize a conservative force in several different ways
    • Specify mathematical conditions that must be satisfied by a conservative force and its components
    • Relate the conservative force between particles of a system to the potential energy of the system
    • Calculate the components of a conservative force in various cases

    In Potential Energy and Conservation of Energy, any transition between kinetic and potential energy conserved the total energy of the system. This was path independent, meaning that we can start and stop at any two points in the problem, and the total energy of the system—kinetic plus potential—at these points are equal to each other. This is characteristic of a conservative force. We dealt with conservative forces in the preceding section, such as the gravitational force and spring force. When comparing the motion of the football in Figure 8.2.1, the total energy of the system never changes, even though the gravitational potential energy of the football increases, as the ball rises relative to ground and falls back to the initial gravitational potential energy when the football player catches the ball. Non-conservative forces are dissipative forces such as friction or air resistance. These forces take energy away from the system as the system progresses, energy that you can’t get back. These forces are path dependent; therefore it matters where the object starts and stops.

    Definition: Conservative Force

    The work done by a conservative force is independent of the path; in other words, the work done by a conservative force is the same for any path connecting two points:

    \[W_{AB,\; path-1} = \int_{AB,\; path-1} \vec{F}_{cons} \cdotp d \vec{r} = W_{AB,\; path-2} = \int_{AB,\; path-2} \vec{F}_{cons} \cdotp d \vec{r} \ldotp \label{8.8}\]

    The work done by a non-conservative force depends on the path taken. Equivalently, a force is conservative if the work it does around any closed path is zero:

    \[W_{closed\; path} = \oint \vec{E}_{cons} \cdotp d \vec{r} = 0 \ldotp \label{8.9}\]

    In Equation \ref{8.9}, we use the notation of a circle in the middle of the integral sign for a line integral over a closed path, a notation found in most physics and engineering texts.] Equations \ref{8.8} and \ref{8.9} are equivalent because any closed path is the sum of two paths: the first going from A to B, and the second going from B to A. The work done going along a path from B to A is the negative of the work done going along the same path from A to B, where A and B are any two points on the closed path:

    \[\begin{split} 0 = \int \vec{F}_{cons} \cdotp d \vec{r} & = \int_{AB,\; path-1} \vec{F}_{cons} \cdotp d \vec{r} + \int_{BA,\; path-2} \vec{F}_{cons} \cdotp d \vec{r} \\ & = \int_{AB,\; path-1} \vec{F}_{cons} \cdotp d \vec{r} - \int_{AB,\; path-2} \vec{F}_{cons} \cdotp d \vec{r} = 0 \ldotp \end{split}\]

    You might ask how we go about proving whether or not a force is conservative, since the definitions involve any and all paths from A to B, or any and all closed paths, but to do the integral for the work, you have to choose a particular path. One answer is that the work done is independent of path if the infinitesimal work \(\vec{F} \cdotp d \vec{r}\) is an exact differential, the way the infinitesimal net work was equal to the exact differential of the kinetic energy, \(dW_{net} = m\vec{v}\; \cdotp d\vec{v}= d \frac{1}{2}mv^{2}\), when we derived the work-energy theorem in Work-Energy Theorem. There are mathematical conditions that you can use to test whether the infinitesimal work done by a force is an exact differential, and the force is conservative. These conditions only involve differentiation and are thus relatively easy to apply. In two dimensions, the condition for \(\vec{F} \cdotp d \vec{r}\) = Fxdx + Fydy to be an exact differential is

    \[\frac{dF_{x}}{dy} = \frac{dF_{y}}{dx} \ldotp \label{8.10}\]

    You may recall that the work done by the force in Example 7.2.4 depended on the path. For that force,

    \[F_{x} = (5\; N/m)y\; and\; F_{y} = (10\; N/m)x \ldotp\]


    \[\left(\dfrac{dF_{x}}{dy}\right) = 5\; N/m \neq \left(\dfrac{dF_{y}}{dx}\right) = 10\; N/m,\]

    which indicates it is a non-conservative force. Can you see what you could change to make it a conservative force?

    A photograph of a grinding wheel being used.
    Figure \(\PageIndex{1}\): A grinding wheel applies a non-conservative force, because the work done depends on how many rotations the wheel makes, so it is path-dependent.
    Example \(\PageIndex{1}\): Conservative or Not?

    Which of the following two-dimensional forces are conservative and which are not? Assume a and b are constants with appropriate units:

    1. \(axy^{3} \hat{i} + ayx^{3} \hat{j},\)
    2. \(a \left[ \left(\dfrac{y^{2}}{x}\right) \hat{i} + 2y \ln \left(\dfrac{x}{b}\right) \hat{j} \right],\)
    3. \(\frac{ax \hat{i} + ay \hat{j}}{x^{2} + y^{2}}\)


    Apply the condition stated in Equation \ref{8.10}, namely, using the derivatives of the components of each force indicated. If the derivative of the y-component of the force with respect to x is equal to the derivative of the x-component of the force with respect to y, the force is a conservative force, which means the path taken for potential energy or work calculations always yields the same results.



    \[\frac{dF_{x}}{dy} = \frac{d(axy^{3})}{dy} = 3axy^{2} \nonumber\]


    \[\frac{dF_{y}}{dx} = \frac{d(ayx^{3})}{dx} = 3ayx^{2}, \nonumber\]

    so this force is non-conservative.


    \[\frac{dF_{x}}{dy} = \frac{d \left(\dfrac{ay^{2}}{x}\right)}{dy} = \frac{2ay}{x} \nonumber\]


    \[\frac{dF_{y}}{dx} = \frac{d(2ay \ln \left(\dfrac{x}{b}\right))}{dx} = \frac{2ay}{x}, \nonumber\]

    so this force is conservative.


    \[\frac{dF_{x}}{dy} = \frac{d \left(\dfrac{ax}{(x^{2} + y^{2})}\right)}{dy} = - \frac{ax(2y)}{(x^{2} + y^{2})^{2}} = \frac{dF_{y}}{dx} = \frac{d \left(\dfrac{ay}{(x^{2} + y^{2})}\right)}{dx },\]

    again conservative.


    The conditions in Equation \ref{8.10} are derivatives as functions of a single variable; in three dimensions, similar conditions exist that involve more derivatives.

    Exercise \(\PageIndex{1}\)

    A two-dimensional, conservative force is zero on the x- and y-axes, and satisfies the condition \(\left(\dfrac{dF_{x}}{dy}\right) = \left(\dfrac{dF_{y}}{dy}\right)\) = (4 N/m3)xy. What is the magnitude of the force at the point \(x = y = 1\, m\)?

    Before leaving this section, we note that non-conservative forces do not have potential energy associated with them because the energy is lost to the system and can’t be turned into useful work later. So there is always a conservative force associated with every potential energy. We have seen that potential energy is defined in relation to the work done by conservative forces. That relation, Equation 8.2.1, involved an integral for the work; starting with the force and displacement, you integrated to get the work and the change in potential energy. However, integration is the inverse operation of differentiation; you could equally well have started with the potential energy and taken its derivative, with respect to displacement, to get the force. The infinitesimal increment of potential energy is the dot product of the force and the infinitesimal displacement,

    \[dU = - \vec{F}\; \cdotp d \vec{l} = - F_{l}dl \ldotp\]

    Here, we chose to represent the displacement in an arbitrary direction by d\(\vec{l}\), so as not to be restricted to any particular coordinate direction. We also expressed the dot product in terms of the magnitude of the infinitesimal displacement and the component of the force in its direction. Both these quantities are scalars, so you can divide by dl to get

    \[F_{l} = - \frac{dU}{dl} \ldotp \label{8.11}\]

    This equation gives the relation between force and the potential energy associated with it. In words, the component of a conservative force, in a particular direction, equals the negative of the derivative of the corresponding potential energy, with respect to a displacement in that direction. For one-dimensional motion, say along the x-axis, Equation \ref{8.11} give the entire vector force,

    \[\bar{F} = F_{x} \hat{i} = - \frac{\partial U}{\partial x} \hat{i} \ldotp\]

    In two dimensions,

    \[ \begin{align} \bar{F} &= F_{x} \hat{i} + F_{y} \hat{j} \\[4pt] &= - \left(\dfrac{\partial U}{\partial x}\right) \hat{i} - \left(\dfrac{\partial U}{\partial y}\right) \hat{j} \ldotp \end{align}\]

    From this equation, you can see why Equation \ref{8.11} is the condition for the work to be an exact differential, in terms of the derivatives of the components of the force. In general, a partial derivative notation is used. If a function has many variables in it, the derivative is taken only of the variable the partial derivative specifies. The other variables are held constant. In three dimensions, you add another term for the z-component, and the result is that the force is the negative of the gradient of the potential energy. However, we won’t be looking at three-dimensional examples just yet.

    Example \(\PageIndex{2}\): Force due to a Quartic Potential Energy

    The potential energy for a particle undergoing one-dimensional motion along the x-axis is

    \[U(x) = \frac{1}{4} cx^{4}, \nonumber\]

    where c = 8 N/m3. Its total energy at x = 0 is 2 J, and it is not subject to any non-conservative forces. Find (a) the positions where its kinetic energy is zero and (b) the forces at those positions.


    1. We can find the positions where K = 0, so the potential energy equals the total energy of the given system.
    2. Using Equation \ref{8.11}, we can find the force evaluated at the positions found from the previous part, since the mechanical energy is conserved.
    1. The total energy of the system of 2 J equals the quartic elastic energy as given in the problem $$2\; J = \frac{1}{4} (8\; N/m^{3}) x_{f}^{4} \ldotp$$Solving for xf results in xf = ±1 m.
    2. From Equation \ref{8.11}, $$F_{x} = - \frac{dU}{dx} = -cx^{3} \ldotp$$ Thus, evaluating the force at ±1 m , we get $$\vec{F} = - (8\; N/m^{3})(\pm 1\; m)^{3} \hat{i} = \pm 8\; N \hat{i} \ldotp$$At both positions, the magnitude of the forces is 8 N and the directions are toward the origin, since this is the potential energy for a restoring force.


    Finding the force from the potential energy is mathematically easier than finding the potential energy from the force, because differentiating a function is generally easier than integrating one.

    Exercise \(\PageIndex{2}\)

    Find the forces on the particle in Example \(\PageIndex{2}\) when its kinetic energy is 1.0 J at \(x = 0\).

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