Friction

Definition Friction is just a force that tries to keep objects from moving. It occurs between materials in contact with each other when they start to slide past each other. But, until the motion begins, friction is not evident.

Types of Friction Between Solids

a) Static (starting) friction is the force preventing motionless surfaces from starting to slide past each

other.

b) If two objects are already sliding past each other, sliding (kinetic) friction is the force required to keep

their relative motion constant.

c) Rolling friction is the force required to keep one object rolling over a surface at constant speed.

Rolling friction is always less than sliding friction.

Friction Summary

1. The frictional force is parallel to the two surfaces in contact with each other and it operates in the

direction that tries to keep them from moving past each other. For example, if you try to push a chair to

the right across the floor, the static friction between the chair legs and the floor pushes to the left, back

at you, trying to stop the chair moving.

2. The amount of frictional force depends on the nature of the materials in contact with each other and

the smoothness of their surfaces. The coefficient of friction, μ, indicates the degree to which the two

surfaces interlock. Actually, if the two surfaces are extremely smooth, friction can actually increase

because so much of the two surfaces is in contact. In space, excessive frictional attraction between two

materials may create a phenomenon called “cold welding”. This may occur when flat, smooth metallic

parts are touching. With no dust layer coating the surfaces, the electrostatic attraction between atoms

in the surfaces may be strong enough to require considerable force, perhaps hammering, to separate

them.

3. Starting friction is always more than sliding friction because the motionless surfaces are interlocked.

But, once the materials are sliding, their microscopic hills and valleys have less chance to settle into

each other and lock up. Imagine a muddy field dotted with closely spaced boulders. Stepping from

boulder to boulder would be an efficient way of crossing the field – no sinking into the mud and so,

much less friction. This type of motion effectively reduces the μ by allowing the surfaces to seem

smoother.

4. The amount of friction is essentially unrelated to the area of contact between the two surfaces. You

still have the same two materials with the same surface textures and so the friction is the same. An

example that is sometimes used is using a spring scale to measure the force needed to break the grip of

friction as you pull a brick across a table. The reading on the scale will be much the same regardless of

which of the brick’s faces is in contact with the table. A bit of care is needed with this type of situation

if the object’s dimensions are very unequal. If it is quite long for example, standing it on end will

concentrate all its weight into a rather small footprint, creating a large downward pressure, i.e., a large

downward force. Then, the force needed to break the grip of friction will be more than when the object

is resting on its side. Why? Because on its side, its weight is spread out over a much larger footprint

which generates less downward pressure, less downward force, and therefore less force is needed to

break the grip of friction. Remember, the nature of the surfaces in contact with each other determines

the μ. The amount of force needed to break friction and the force jamming the two materials together

must remain in the same ratio to each other, equal to the μ.

5. As just noted above, the amount of frictional force is directly proportional to the normal force pushing

the surfaces together. The more forcefully the two surfaces are jammed together, the more energy it

takes to get them sliding past each other. It takes more force to slide a full crate across a floor than an

empty one. But remember, the μ is unchanged – the same floor and the same crate, loaded or full.

6. As motion begins, the μ decreases as the situation changes from static to sliding friction and the force

needed to keep the motion going is less than to get it started. But, once the object is under way,

increasing the speed has no further effect on the μ and so has no more effect on the frictional force.

This is true so long as the speed is not too high. Extreme speeds may cause enough frictional heating to

result in a melt zone where the two surfaces are in contact and this moves the situation into that

of liquid friction.

Some Selected μ Values

Surfaces Static Sliding

Steel on steel 0.74 0.57

Wood on wood 0.50 0.30

Rubber tire (dry road) 0.70

Rubber tire (wet road) 0.50

Friction Calculations

1. Horizontal Surfaces

Q. a) Calculate the force required to start a 30 N piece of steel moving along a horizontal steel surface.

b) Once the steel is sliding, what force is then required to keep it moving along at a constant speed?

c) What would happen to the block in b) if 25 N were applied to it?

Use the following equation: μ = F/N. The F is sometimes written as F_F or F_R. The F_F stands for “the

frictional force to overcome”, and F_R stands for “the required force to overcome friction”. Use any one of them – it just depends on the wording of the question. Also, F_N is sometimes written as just N. In either case, it means the force directed straight into (normal) to the supporting surface. When the supporting surface is horizontal, the N (or F_N) is just the object’s weight. Now, the solution.

a) μ = F_R or F_R = μ * F_N = 0.74 * 30 N = 22.2 N

F_N

b) μ = F_R or F_R = μ * F_N = 0.57 * 30 N = 17.1 N Notice we use the μ for sliding friction.

F_N

c) Any excess force causes the block to accelerate, after the F gets it moving first.

i) change the object’s weight to its mass using W = mg; m = W/g = 30 N / 9.8 m/s² = 3.06 kg

ii) find the excess force; 25 N – 17.1 N = 7.9 N

iii) now, find the acceleration; F = ma or a = F / m = 7.9 N / 3.06 kg = 2.58 m/s²

2 A. Inclined Surfaces: Descending Motion, Only Gravity

Q. A 20 N wooden block just slides down a 17⁰ wooden incline at constant speed. Find the coefficient of

friction of the two surfaces.

The thing to understand is that the object’s weight acts straight down but the geometry of the situation

creates two components of the weight. One component pushes the block straight into the surface of the

ramp so this component is the F_N. The other component of the block’s weight, F∥, is directed down the

ramp, parallel to its surface. This component tries to move the block down the ramp but the friction force (F) works against it. In this problem, the F∥ is successful; no other push or pull is required to get the block moving down and so the F∥ is large enough to be called F. Of course, if the object does not move, the F∥ is too small to be called F because F is the amount of force needed to cause motion. Just because F∥ and F are both parallel to the ramp does not mean the F∥ will be always be successful in breaking the grip of friction and moving the object.

The geometry of ramp problems shows that, as the ramp angle increases, the F_N decreases and the F∥ increases. Recall that the μ determines the relative sizes of the F and F_N – whenever the F_N lessens, so does the F. So, at steep angles both the F_N and the F become less but the F∥ becomes larger. At ramp angles beyond a certain steepness, the F∥ will be larger than F and so, down slides the object. Whenever an object on a ramp slides down on its own, we know the F∥ component of the object’s weight is larger than the F trying to keep it from moving.

a) Find the weight components; F_N = cos 17⁰ * 20 N = 0.956 * 20 N = 19.12 N

F∥ = sin 17⁰ * 20 N = 0.292 * 20 N = 5.85 N

b) The only force acting on the object to overcome friction is F∥. Because the object slides at a constant

rate, we know F∥ is just equal to the friction force. And so, we can substitute F∥ for F and write that

μ = F∥ / F_N. So then, μ = 5.85 N / 19.12 N = 0.306.

2 B. Inclined Surfaces: Descending Motion, Gravity Plus Pushing

Q. A 45 N crate sits on a 10⁰ ramp. If the μ is 0.5, what force is required to push it down the ramp?

Because the crate is not moving, we know the F∥ is not large enough to overcome F and therefore an

additional push is necessary.

a) Find the weight components; F_N = cos 10⁰ * 45 N = 0.985 * 45 N = 44.31 N

F∥ = sin 10⁰ * 45 N = 0.174 * 45 N = 7.83 N

b) Find the friction force to be overcome; μ = F / F_N or F = μ * F_N = 0.5 * 44.31 N = 22.15 N

c) Find the extra push required. We know the friction force (F) keeps the crate locked on the ramp’s

surface with a grip of 22.15 N. But remember, the object’s F∥ weight component is already trying to

push it down-ramp with 7.83 N. So, we need an additional push of: 22.15 N – 7.83 N = 14.32 N.

3. Inclined Surfaces: Ascending Motion

Q. What force is required to start a 30 N wooden block up a 15⁰ wooden incline at constant speed? (The

block is stationary and the static μ from the list is 0.5.)

Again, the block’s weight must be resolved into the F_N and F∥ components. Also, since the block is being moved up the incline, two forces must be overcome – friction (F) and the block’s F∥ weight component. Why two forces to overcome? Friction must always be overcome. And, in this problem, the block is being dragged uphill so its own F∥ acts against it. The F∥ is always downslope – last time it helped because the object’s motion was downslope. But, this time it hinders because the object’s motion is upslope ands so it acts against it.

a) Find the weight components; F_N = cos 15⁰ * 30 N = 0.966 * 30 N = 28.98 N

F∥ = sin 15⁰ * 30 N = 0.259 * 30 N = 7.77 N

b) Find the friction force to be overcome; μ = F / F_N or F = μ * F_N = 0.5 * 28.98 N = 11.49 N

c) Find the combined forces to overcome, F∥ + F; 7.77 N + 11.49 N = 19.26 N

4. Horizontal Surface: Pulling Up on Handle

Q. A 27 N sled is pulled across the snow (μ = 0.2) by a child who pulls up on its tow rope with 50 N. If

the rope angles up at 38⁰ and the child’s force is just sufficient to move the sled, what weight can the

child drag on the it?

The child must pull on the rope with more force than if all her efforts were directed horizontally. Because

of the geometry of the situation, only part of her energy, only the F_H component, is available to try to move the sled. The upward component of her pulling force, the F_V component, lessens the sled’s weight so more “cargo” can be pulled. This last point is the reason you can pull more weight than you can push.

a) Vertical force component (F_VERTICAL or F_V) = sin 38⁰ * 50 N = 0.616 * 50 N = 30.8 N

Horizontal force component (F_HORIZONTAL or F_H) = cos 38⁰ * 50 N = 0.788 * 50 N = 39.4 N

b) Because we are told the child can just pull the sled, we know the F_H component of her pulling force

will be enough to overcome friction and so, F_H = F = 39.4 N.

c) To find the total weight the child’s F_H can move, we find the F_N. This value is the total of the sled and

its cargo. F_N = F / μ = 39.4 N / 0.2 = 197 N. By the way, notice that because the snow is slick, a large

F_N (197 N) can be moved with a small F_H (39.4 N.)

d) The sled weighs only 27 N but 197 N can be moved. So, to find the cargo, we subtract:

197 N – 27 N = 170 N of cargo. But, recall that the child’s F_V reduces the sled’s weight by 30.8 N.

So, another 30.8 N can be loaded onto the sled. Now, the total cargo is 170 N + 30.8 N = 200.8 N.

5. Horizontal Surface: Pushing Down on Handle

Q. A gardener moves a 2 N hand plow across a patch of ground (μ = 1.3) by pushing down its handle

with 37 N. If the handle dips at 24⁰ and the gardener’s force is just sufficient to move the plow, what

weight of soil (cargo) can it carry?

Because the force is at an angle, the person must push with more force than if her efforts were all

horizontal because only the F_H component of her effort is moving the plow. The downward component of her pushing force, the F_V component, increases the effective weight of the plow and so the amount of “cargo” her F_H force component can move is reduced. In contrast to pulling, pushing lessens how much we can move.

a) Vertical force component (F_VERTICAL or F_V) = sin 24⁰ * 37 N = 0.407 * 37 N = 15.06 N

Horizontal force component (F_HORIZONTAL or F_H) = cos 24⁰ * 37 N = 0.914 * 37 N = 33.82 N

b) Because the gardener’s force is just sufficient to move the plow, we know the F_H of her pushing force

will equal friction and so F_H = F = 33.82 N. To find the total weight that can be moved, use

F_N = F / μ = 3.82 N / 1.3 = 26.02 N. See that because the soil is rough and friction is large, it takes a

large F_H (33.82 N) to move a smaller weight (26.02 N).

d) Although 26.01 N can be moved by the girl’s F_H component, the plow weighs just 2 N and so the

amount of soil that can be moved is: 26.01 N – 2 N = 24.02 N. But, recall the F_V component of the

girl’s pushing force increases the plow’s weight by another 15.06 N. This further reduces the amount

of soil that can be moved: 24.02 N – 15.06 N = 8.96 N. Note: If the soil were rougher or the girl’s

pushing angle were steeper, there would be so much friction that her F_V would not be enough to move

even the plow itself! In such a case, this last calculation, the amount of soil that could be moved,

would yield a negative value.