Learning Objectives

Learning Objectives

By the end of this section, you will be able to do the following:

  • Define nonconservative forces and explain how they affect mechanical energy
  • Show how the principle of conservation of energy can be applied by treating the conservative forces in terms of their potential energies and any nonconservative forces in terms of the work they do

The information presented in this section supports the following AP® learning objectives and science practices:

  • 4.C.1.2 The student is able to predict changes in the total energy of a system due to changes in position and speed of objects or frictional interactions within the system. (S.P. 6.4)
  • 4.C.2.1 The student is able to make predictions about the changes in the mechanical energy of a system when a component of an external force acts parallel or antiparallel to the direction of the displacement of the center of mass. (S.P. 6.4)

Nonconservative Forces and Friction

Nonconservative Forces and Friction

Forces are either conservative or nonconservative. Conservative forces were discussed in Conservative Forces and Potential Energy. A nonconservative force is one for which work depends on the path taken. Friction is a good example of a nonconservative force. As illustrated in Figure 7.15, work done against friction depends on the length of the path between the starting and ending points. Because of this dependence on path, there is no potential energy associated with nonconservative forces. An important characteristic is that the work done by a nonconservative force adds or removes mechanical energy from a system. Friction, for example, creates thermal energy that dissipates, removing energy from the system. Furthermore, even if the thermal energy is retained or captured, it cannot be fully converted back to work, so it is lost or not recoverable.

(a) A drawing of a happy face is erased diagonally from a point A to a point B. (b) A drawing of a happy face is erased in the shape of the letter u, but starting from the same point A and ending at the same point B.
Figure 7.15 The amount of the happy face erased depends on the path taken by the eraser between points A and B, as does the work done against friction. Less work is done and less of the face is erased for the path in (a) than for the path in (b). The force here is friction, and most of the work goes into thermal energy that subsequently leaves the system—the happy face plus the eraser. The energy expended cannot be fully recovered.

How Nonconservative Forces Affect Mechanical Energy

How Nonconservative Forces Affect Mechanical Energy

Mechanical energy may not be conserved when nonconservative forces act. For example, when a car is brought to a stop by friction on level ground, it loses kinetic energy, which is dissipated as thermal energy, reducing its mechanical energy. Figure 7.16 compares the effects of conservative and nonconservative forces. We often choose to understand simpler systems such as the system described in Figure 7.16(a) before studying more complicated systems, as in Figure 7.16(b).

(a) A system is shown in three situations. First, a rock is dropped onto a spring attached to the ground. The rock has potential energy P E sub 0 at the highest point before it is dropped on the spring. In the second situation, the rock has fallen onto the spring and the spring is compressed and has potential energy P E sub s. And in the third situation, the spring pushes the rock into the air; then the rock has some kinetic and some potential energy, labeled as K E plus P E sub g prime. (b) A rock is at
Figure 7.16 Comparison of the effects of conservative and nonconservative forces on the mechanical energy of a system. (a) A system with only conservative forces. When a rock is dropped onto a spring, its mechanical energy remains constant, neglecting air resistance, because the force in the spring is conservative. The spring can propel the rock back to its original height, where it once again has only potential energy due to gravity. (b) A system with nonconservative forces. When the same rock is dropped onto the ground, it is stopped by nonconservative forces that dissipate its mechanical energy as thermal energy, sound, and surface distortion. The rock has lost mechanical energy.

How the Work-Energy Theorem Applies

How the Work-Energy Theorem Applies

Now let us consider what form the work-energy theorem takes when both conservative and nonconservative forces act. We will see that the work done by nonconservative forces equals the change in the mechanical energy of a system. As noted in Kinetic Energy and the Work-Energy Theorem, the work-energy theorem states that the net work on a system equals the change in its kinetic energy, or Wnet=ΔKEWnet=ΔKE size 12{W rSub { size 8{"net"} } =D"KE"} {}. The net work is the sum of the work by nonconservative forces plus the work by conservative forces. That is,

7.61 Wnet=Wnc+Wc,Wnet=Wnc+Wc, size 12{W rSub { size 8{"net"} } =W rSub { size 8{"nc"} } +W rSub { size 8{c} } } {}

so that

7.62 Wnc+Wc=ΔKE,Wnc+Wc=ΔKE, size 12{W rSub { size 8{"nc"} } +W rSub { size 8{c} } =Δ"KE"} {}

where WncWnc size 12{W rSub { size 8{"nc"} } } {} is the total work done by all nonconservative forces and WcWc size 12{W rSub { size 8{c} } } {} is the total work done by all conservative forces.

A person pushing a heavy box up an incline. A force F p applied by the person is shown by a vector pointing up the incline. And frictional force f is shown by a vector pointing down the incline, acting on the box.
Figure 7.17 A person pushes a crate up a ramp, doing work on the crate. Friction and gravitational force (not shown) also do work on the crate; both forces oppose the person’s push. As the crate is pushed up the ramp, it gains mechanical energy, implying that the work done by the person is greater than the work done by friction.

Consider Figure 7.17, in which a person pushes a crate up a ramp and is opposed by friction. As in the previous section, we note that work done by a conservative force comes from a loss of gravitational potential energy, so that Wc=ΔPEWc=ΔPE size 12{W rSub { size 8{c} } = - Δ"PE"} {}. Substituting this equation into the previous one and solving for WncWnc size 12{W rSub { size 8{"nc"} } } {} gives

7.63 Wnc=ΔKE+ΔPE.Wnc=ΔKE+ΔPE. size 12{W rSub { size 8{"nc"} } =Δ"KE"+Δ"PE"} {}

This equation means that the total mechanical energy (KE + PE)(KE + PE) size 12{ \( "KE + PE" \) } {} changes by exactly the amount of work done by nonconservative forces. In Figure 7.17, this is the work done by the person minus the work done by friction. So even if energy is not conserved for the system of interest, such as the crate, we know that an equal amount of work was done to cause the change in total mechanical energy.

We rearrange Wnc=ΔKE+ΔPEWnc=ΔKE+ΔPE size 12{W rSub { size 8{"nc"} } =D"KE"+D"PE"} {} to obtain

7.64 KEi+PEi+Wnc= KE f +PEf.KEi+PEi+Wnc= KE f +PEf. size 12{"KE""" lSub { size 8{i} } +"PE" rSub { size 8{i} } +W rSub { size 8{"nc"} } ="KE""" lSub { size 8{f} } +"PE" rSub { size 8{f} } } {}

This equation means that the amount of work done by nonconservative forces adds to the mechanical energy of a system. If WncWnc size 12{W rSub { size 8{"nc"} } } {} is positive, then mechanical energy is increased, such as when the person pushes the crate up the ramp in Figure 7.17. If WncWnc size 12{W rSub { size 8{"nc"} } } {} is negative, then mechanical energy is decreased, such as when the rock hits the ground in Figure 7.16(b). If WncWnc size 12{W rSub { size 8{"nc"} } } {} is zero, then mechanical energy is conserved, and nonconservative forces are balanced. For example, when you push a lawn mower at constant speed on level ground, your work done is removed by the work of friction, and the mower has a constant energy.

Applying Energy Conservation with Nonconservative Forces

Applying Energy Conservation with Nonconservative Forces

When no change in potential energy occurs, applying KEi+PEi+Wnc= KE f +PEfKEi+PEi+Wnc= KE f +PEf size 12{"KE""" lSub { size 8{i} } +"PE" rSub { size 8{i} } +W rSub { size 8{"nc"} } ="KE""" lSub { size 8{f} } +"PE" rSub { size 8{f} } } {} amounts to applying the work-energy theorem by setting the change in kinetic energy to be equal to the net work done on the system, which in the most general case includes both conservative and nonconservative forces. When seeking instead to find a change in total mechanical energy in situations that involve changes in both potential and kinetic energy, the previous equation KE i + PEi + Wnc = KE f + PEf KE i + PEi + Wnc = KE f + PEf size 12{"KE""" lSub { size 8{i} } +"PE" rSub { size 8{i} } +W rSub { size 8{"nc"} } ="KE""" lSub { size 8{f} } +"PE" rSub { size 8{f} } } {} says that you can start by finding the change in mechanical energy that would have resulted from just the conservative forces, including the potential energy changes, and add to it the work done, with the proper sign, by any nonconservative forces involved.

Example 7.9 Calculating Distance Traveled: How Far a Baseball Player Slides

Consider the situation shown in Figure 7.18, where a baseball player slides to a stop on level ground. Using energy considerations, calculate the distance the 65.0-kg baseball player slides, given that his initial speed is 6.00 m/s and the force of friction against him is a constant 450 N.

A baseball player slides to stop in a distance d. the displacement d is shown by a vector towards the left and frictional force f on the player is shown by a small vector pointing towards the right equal to four hundred and fifty newtons. K E is equal to half m v squared, which is equal to f times d.
Figure 7.18 The baseball player slides to a stop in a distance dd size 12{d} {}. In the process, friction removes the player’s kinetic energy by doing an amount of work fdfd size 12{ ital "fd"} {} equal to the initial kinetic energy.

Strategy

Friction stops the player by converting his kinetic energy into other forms, including thermal energy. In terms of the work-energy theorem, the work done by friction, which is negative, is added to the initial kinetic energy to reduce it to zero. The work done by friction is negative, because ff size 12{f} {} is in the opposite direction of the motion (that is, θ=180ºθ=180º size 12{q="180"°} {}, and so cosθ=1cosθ=1 size 12{"cos"θ= - 1} {}). Thus, Wnc=fdWnc=fd size 12{W rSub { size 8{"nc"} } = - ital "fd"} {}. The equation simplifies to

7.65 1 2 mv i 2 fd = 0 1 2 mv i 2 fd = 0 size 12{ { {1} over {2} }  ital "mv" rSub { size 8{i} rSup { size 8{2} } } - ital "fd"=0} {}

or

7.66 fd = 1 2 mv i 2 . fd = 1 2 mv i 2 . size 12{ ital "fd"= { {1} over {2} }  ital "mv" rSub { size 8{i} rSup { size 8{2} } } "." } {}

This equation can now be solved for the distance dd size 12{d} {}.

Solution

Solving the previous equation for dd size 12{d} {} and substituting known values yields

7.67 d = mv i 2 2f = ( 65.0 kg ) ( 6 . 00 m/s ) 2 ( 2 ) ( 450 N ) = 2.60 m. d = mv i 2 2f = ( 65.0 kg ) ( 6 . 00 m/s ) 2 ( 2 ) ( 450 N ) = 2.60 m. alignl { stack { size 12{d= { { ital "mv" rSub { size 8{i} rSup { size 8{2} } } } over {2f} } } {} # = { { \( "65" "." 0" kg" \) \( 6 "." "00"" m/s" \) rSup { size 8{2} } } over { \( 2 \) \( "450"" N" \) } } {} # " "=" 2" "." "60 m" "." {} } } {}

Discussion

The most important point of this example is that the amount of nonconservative work equals the change in mechanical energy. For example, you must work harder to stop a truck, with its large mechanical energy, than to stop a mosquito.

Example 7.10 Calculating Distance Traveled: Sliding Up an Incline

Suppose that the player from Example 7.9 is running up a hill having a 5.00º5.00º size 12{5 "." "00"°} {} incline upward with a surface similar to that in the baseball stadium. The player slides with the same initial speed. Determine how far he slides.

A baseball player slides on an inclined slope represented by a right triangle. The angle of the slope is represented by the angle between the base and the hypotenuse, which is equal to five degrees, and the height h of the perpendicular side of the triangle is equal to d sin 5 degrees. The length of the hypotenuse is d.
Figure 7.19 The same baseball player slides to a stop on a 5.00º5.00º size 12{5°} {} slope.

Strategy

In this case, the work done by the nonconservative friction force on the player reduces the mechanical energy he has from his kinetic energy at zero height, to the final mechanical energy he has by moving through distance dd size 12{d} {} to reach height hh size 12{h} {} along the hill, with h=dsin5.00ºh=dsin5.00º size 12{h=d"sin"5 "." "00"°} {}. This is expressed by the equation

7.68 KEii+PEi+Wnc= KE f + PEf.KEii+PEi+Wnc= KE f + PEf. size 12{"KE""" lSub { size 8{i} } +"PE" rSub { size 8{i} } +W rSub { size 8{"nc"} } ="KE""" lSub { size 8{f} } +"PE" rSub { size 8{f} } } {}

Solution

The work done by friction is again Wnc=fdWnc=fd size 12{W rSub { size 8{"nc"} } = - ital "fd"} {}; initially the potential energy is PEi=mg0=0PEi=mg0=0 and the kinetic energy is KEi=12mvi2KEi=12mvi2. The final energy contributions are KEf=0KEf=0 size 12{"KE" rSub { size 8{f} } =0} {} for the kinetic energy and PEf=mgh=mgdsinθPEf=mgh=mgdsinθ size 12{"PE" rSub { size 8{f} } = ital "mgh"= ital "mgd""sin"θ} {} for the potential energy.

Substituting these values gives

7.69 1 2 mv i 2 + 0 + ( fd ) = 0 + mgd sin θ. 1 2 mv i 2 + 0 + ( fd ) = 0 + mgd sin θ.

Solve this for dd to obtain

7.70 d = 1 2 mv i 2 f + mg sinθ = (0.5) ( 65.0 kg ) ( 6.00 m/s ) 2 450 N + ( 65.0 kg ) ( 9.80 m/s 2 ) sin (5.00º) = 2.31 m. d = 1 2 mv i 2 f + mg sinθ = (0.5) ( 65.0 kg ) ( 6.00 m/s ) 2 450 N + ( 65.0 kg ) ( 9.80 m/s 2 ) sin (5.00º) = 2.31 m. alignl { stack { size 12{d = { { left ( { {1} over {2} } right ) ital "mv""" lSub { size 8{i} } "" lSup { size 8{2} } } over {f+ ital "mg""sin5" rSup { size 8{ circ } } } } } {} # " "= { {0 "." "5 " \( "65" "." "0 kg" \) \( 6 "." "00 m/s" \) rSup { size 8{2} } } over {"450""N "+ \( "65" "." "0 kg" \) \( 9 "." "80 m/s" rSup { size 8{2} } \) "sin 5" rSup { size 8{ circ } } } } {} # " "=2 "." "31 m" "." {} } } {}

Discussion

As you may expect, the player slides a shorter distance when sliding uphill. Note that the problem could also have been solved in terms of the forces directly and the work-energy theorem, instead of using the potential energy. This method would have required combining the normal force and force of gravity vectors, which no longer cancel each other because they point in different directions, and friction, to find the net force. You could then use the net force and the net work to find the distance dd size 12{d} {} that reduces the kinetic energy to zero. By applying conservation of energy and using the potential energy instead, we need only consider the gravitational potential energy mghmgh size 12{ ital "mgh"} {}, without combining and resolving force vectors. This approach considerably simplifies the solution.

Making Connections: Take-Home Investigation—Determining Friction from the Stopping Distance

This experiment involves the conversion of gravitational potential energy into thermal energy. Use the ruler, book, and marble from Figure 7.8. In addition, you will need a foam cup with a small hole in the side, as shown in Figure 7.20. From the 10-cm position on the ruler, let the marble roll into the cup positioned at the bottom of the ruler. Measure the distance dd size 12{d} {} the cup moves before stopping. What forces caused it to stop? What happened to the kinetic energy of the marble at the bottom of the ruler? Next, place the marble at the 20-cm and the 30-cm positions and again measure the distance the cup moves after the marble enters it. Plot the distance the cup moves versus the initial marble position on the ruler. Is this relationship linear?

With some simple assumptions, you can use these data to find the coefficient of kinetic friction μkμk size 12{μ rSub { size 8{k} } } {} of the cup on the table. The force of friction ff on the cup is μkNμkN size 12{μ rSub { size 8{k} } N} {}, where the normal force NN is the weight of the cup plus the marble. The normal force and force of gravity do no work because they are perpendicular to the displacement of the cup, which moves horizontally. The work done by friction is fdfd size 12{ ital "fd"} {}. You will need the mass of the marble as well to calculate its initial kinetic energy.

It is interesting to do the experiment also with a steel marble or ball bearing. Releasing it from the same positions on the ruler as you did with the glass marble, is the velocity of this steel marble the same as the velocity of the marble at the bottom of the ruler? Is the distance the cup moves proportional to the mass of the steel and glass marbles?

A marble is rolling down a makeshift ramp consisting of a small wooden ruler propped up on one end at about a thirty degree angle. At the bottom of the ramp is a foam drinking cup standing upside-down on its lip. A hole is cut out on one side of the cup so that the marble will roll through the hole when it reaches the bottom of the ramp.
Figure 7.20 Rolling a marble down a ruler into a foam cup.

PhET Explorations: The Ramp

Explore forces, energy, and work as you push household objects up and down a ramp. Lower and raise the ramp to see how the angle of inclination affects the parallel forces acting on the file cabinet. Graphs show forces, energy, and work.

This icon links to a P H E T Interactive activity when clicked.
Figure 7.21 The Ramp