Infinite coefficient of friction

Click For Summary

Discussion Overview

The discussion revolves around the concept of friction in the context of a ball rolling on a loop-the-loop track. Participants explore the implications of requiring an infinite coefficient of friction for the ball to complete the loop, questioning the logic behind this assertion and examining the relationship between friction, normal force, and motion in both loop and incline scenarios.

Discussion Character

  • Debate/contested
  • Technical explanation
  • Mathematical reasoning

Main Points Raised

  • Some participants question the logic of needing an infinite coefficient of friction for a ball to complete a loop, noting that if both friction and normal force are finite, the coefficient cannot be infinite.
  • Others argue that an infinite coefficient of static friction would imply no sliding, suggesting that sufficient friction combined with speed is adequate for the ball to roll without slipping.
  • A participant mentions that the minimum friction coefficient for pure rolling on an incline can be expressed as a function of the angle, leading to confusion about the implications for a vertical loop.
  • One participant provides a mathematical derivation related to friction and rolling, indicating that the normal force in a loop context differs from that on an incline due to the acceleration involved.
  • A self-declared expert clarifies that the assumption of infinite friction is often used to simplify problems, indicating that it does not imply the necessity of an infinite friction coefficient in practical scenarios.
  • Another participant emphasizes that the analysis of a ball rolling down an incline does not directly apply to the loop situation, as the dynamics differ significantly due to the curvature of the path.

Areas of Agreement / Disagreement

Participants express disagreement regarding the necessity of an infinite coefficient of friction, with some asserting it is not required while others maintain that the concept is valid in certain contexts. The discussion remains unresolved with multiple competing views on the topic.

Contextual Notes

The discussion highlights the complexity of friction in different scenarios, including the need for a minimum friction coefficient for rolling without slipping and the role of normal force in various situations. There are unresolved assumptions regarding the application of friction concepts between inclined planes and loops.

jontyjashan
Messages
68
Reaction score
0
If we set a ball rolling on a loop-the-loop track,why do we say that we need infinite friction coefficient for the ball to complete the loop. This seems illogical because f=kN. Since f and N are finite how can k be infinite ?
 
Physics news on Phys.org
jontyjashan said:
If we set a ball rolling on a loop-the-loop track,why do we say that we need infinite friction coefficient for the ball to complete the loop.
Where did you see this statement?
 
jontyjashan said:
If we set a ball rolling on a loop-the-loop track,why do we say that we need infinite friction coefficient for the ball to complete the loop. This seems illogical because f=kN. Since f and N are finite how can k be infinite ?

Seems nonsensical. Wouldn't an infinite coefficient of friction say that you can't move an object at all?
 
phinds said:
Wouldn't an infinite coefficient of friction say that you can't move an object at all?
It just would mean there's no slippage while the ball is rolling. Infinite friction isn't required. You just need enough friction combined with enough speed and the related centripetal force to keep the ball rolling and not sliding, even when at the top of the loop.
 
rcgldr is correct- an infinite coefficient of *static* friction simply means there is never any sliding, no matter how fast the ball is rolling. Static friction does no work.

That said, an infinite coefficient of static friction is not *required*- all that's needed for the ball (or any object, sliding or not) to complete a vertical loop is that the normal force does not vanish.
 
But if we look at the friction required on inclined plane for rolling it is some function of tan x . So if we look at the rightmost point of the loop at the height of radius the coeff would be some function of tan90 which is infinite
 
jontyjashan said:
But if we look at the friction required on inclined plane for rolling it is some function of tan x .
Why do you think this?
 
I don't think this. Physics says this and it can be proved easily using concept of pure rolling and solving some eqns
 
jontyjashan said:
Physics says this and it can be proved easily using concept of pure rolling and solving some eqns
Please show us!
 
  • #10
Just try it once yourself and btw you can find it in any good standard physics book.
 
  • #11
jontyjashan said:
Just try it once yourself and btw you can find it in any good standard physics book.
Nonsense. If it's so simple, just show us. (I suspect you are mixing up a few concepts or situations.)
 
  • #12
Let f be friction.
Then mgsinx-f=ma(linear)
Also equating torque we get
fR=I@(angular acceleration)
and a=R@ for pure rolling
Solving this v get
f=Ia/R^2
And a = gsinx/1 + I/MR^2

So finally we have minimum friction coefficient for pure rolling is tanx/1 + MR^2/I
 
  • #13
jontyjashan said:
Let f be friction.
Then mgsinx-f=ma(linear)
Also equating torque we get
fR=I@(angular acceleration)
and a=R@ for pure rolling
Solving this v get
f=Ia/R^2
And a = gsinx/1 + I/MR^2

So finally we have minimum friction coefficient for pure rolling is tanx/1 + MR^2/I
OK, I see what you're saying now. That's for rolling down an incline. Note that there is no acceleration normal to the surface, so only the normal component of gravity is available to provide the normal force. So if you have too steep an incline there will not be enough friction to produce rolling without slipping. (Another way of saying that is to claim an 'infinite' coefficient is required, which is clearly unphysical.)

My apologies for not seeing what you meant right away! :redface:

Things are different in the loop, since there's a minimum speed to maintain contact and there's acceleration normal to the surface. The normal force is not equal to the normal component of the weight.
 
Last edited:
  • #14
Still my query is not solved
 
  • #15
jontyjashan said:
Still my query is not solved
Your statement about needing an infinite coefficient of friction was based on rolling without slipping down an incline (with infinite slope). The loop situation is different as there is acceleration normal to the surface.
 
  • #16
Infinite friction

A few comments and clarifications from a self-declared relative expert
(My PhD was about friction, I have written a textbook about mechanics):

1) When proposing or modeling problems where there could conceivably be slip, people often say "assume infinite friction". This doesn't mean that the problem solution depends on infinite friction, it only means you are supposed to assume there is no slip. For most such problems, like this roller coaster one, there is some finite value of friction that is big enough to make there be no slipping, in this case just rolling. You just "assume infinite friction" so as not to worry about it. They should better say, probably, assume no sliding.

2) For the real experts: Actually infinite friction does not always imply no sliding. It only implies that the normal force be zero when there is sliding. There are several mechanics problems where the solution is sensible when the friction coefficient is infinite, the sliding force is finite, and the normal force is zero. A great classic one is the rolling of a wheel on a journal bearing. Even when the journal bearing has infinite coefficient of friction the resistance to rolling is finite. That one example is in my book (google Ruina book for a pdf, in box 4.6. Please cite Ruina/Pratap text if you use this.).
 
  • #17
jontyjashan said:
Let f be friction.
Then mgsinx-f=ma(linear)
Also equating torque we get
fR=I@(angular acceleration)
and a=R@ for pure rolling
Solving this v get
f=Ia/R^2
And a = gsinx/1 + I/MR^2

So finally we have minimum friction coefficient for pure rolling is tanx/1 + MR^2/I

You are assuming that all normal force comes from the normal component of gravity (which would be true, for a ball rolling down a constant incline). This also explains your result - if all the normal force comes from the normal component of gravity, the normal force will be zero for a vertical slope, thus the coefficient of friction would have to be infinite (and it would have to be negative during the top part of the loop, where the angle is greater than 90 degrees by the same logic). This is clearly nonsensical, since we know that a ball can traverse a loop without slipping, and an infinite friction coefficient does not exist.In the case of a loop however, some of the normal force comes from the fact that the ball is experiencing acceleration normal to the surface due to the curvature of the path. Thus, your analysis is not relevant to the situation (since a ball going around a loop is an entirely different scenario from a ball rolling down a constant incline).
 
Last edited:

Similar threads

High School How will a spring stretch in the following cases?
  • · Replies 17 ·
Replies
17
Views
2K
High School Rolling Without Slipping on an Inclined Plane
  • · Replies 5 ·
Replies
5
Views
4K
High School Questions about momentum and force as well as normal force/friction
  • · Replies 35 ·
2
Replies
35
Views
5K
High School Measuring the coefficient of friction
  • · Replies 1 ·
Replies
1
Views
1K
High School Deriving formula for force by thought experiment
  • · Replies 12 ·
Replies
12
Views
2K
Undergrad I would like a better understanding of friction and hysteresis
  • · Replies 5 ·
Replies
5
Views
3K
Graduate Tank tracks treads friction coefficient
  • · Replies 7 ·
Replies
7
Views
10K
Undergrad Rolling Without Slipping
  • · Replies 59 ·
2
Replies
59
Views
5K
Undergrad The coefficient of kinetic friction for a Ford Focus
  • · Replies 6 ·
Replies
6
Views
2K
High School The physics of flywheel launchers (like tennis ball shooters)
  • · Replies 60 ·
3
Replies
60
Views
7K