When does Newton's Second Law not hold?

In summary: Advanced calculus.In summary, this high school student thinks that Newton's Second Law does not hold if the mass is changing with time. However, if you use the instantaneous mass instead of the mass at a particular point in time, the law still holds.
  • #1
shinwolf14
14
0
I know a high school student who has this question. My first thought was that it does not hold if the mass is changing with time. I was thinking of the situation of a snowball rolling down a mountain picking up more snow as it rolls to the bottom. There is obviously mass gained so does Newton's Second Law hold for this situation at the very basic level (for a high school physics question)? If it does, can you think of a situation where it wouldn't hold? Remember that this is a high school introductory course in Physics
 
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  • #2
shinwolf14 said:
I know a high school student who has this question. My first thought was that it does not hold if the mass is changing with time. I was thinking of the situation of a snowball rolling down a mountain picking up more snow as it rolls to the bottom. There is obviously mass gained so does Newton's Second Law hold for this situation at the very basic level (for a high school physics question)?
Yes it does. You just have to use the instantaneous mass.

shinwolf14 said:
If it does, can you think of a situation where it wouldn't hold? Remember that this is a high school introductory course in Physics
Maybe in non-inertial reference frames, unless you introduce inertial forces to make it work again.
 
  • #3
Wikipedia said:
Newton's second law is only valid for constant-mass systems
http://en.wikipedia.org/wiki/Newton's_laws_of_motion#Newton.27s_second_law

I think A.T. is right about using instantaneous mass, but a high school student ("at the very basic level") would probably just learn what the quote from wikipedia says.
 
  • #4
If mass is changing rather than [itex] F= ma[/itex] use [itex]F= d(mv)/dt= m (dv/dt)+ (dm/dt)v= ma+ (dm/dt)v [itex].
 
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  • #5
According to wikipedia when mass is changing the equation that holds in the case of mass variable systems is [tex]F=m\frac{dv}{dt}-v_{rel}\frac{dm}{dt}[/tex]. This is different if we use instanteneous mass only and is not exactly the same as dp/dt because [itex]v_{rel}[/itex] is the relative velocity of the incoming or outgoing mass relative to the c.o.m of the main body.

http://en.wikipedia.org/wiki/Variable-mass_system
 
  • #6
A plague on all smartarse high school questions that are given to students without a thought as to their reaction. People who ask unanswerable questions of their students should be locked in a room with a dozen such questions (aimed just above their level) and not let out till they have answered them. (No access to PF either!)
 
  • #7
sophiecentaur said:
A plague on all smartarse high school questions that are given to students without a thought as to their reaction. People who ask unanswerable questions of their students should be locked in a room with a dozen such questions (aimed just above their level) and not let out till they have answered them. (No access to PF either!)

Well maybe you are right hehe, at least those type of questions shouldn't put in written tests. It is just an extra term added though in Newton's Law familiar form F=ma.
 
  • #8
Delta² said:
This is different if we use instanteneous mass only and is not exactly the same as dp/dt because [itex]v_{rel}[/itex] is the relative velocity of the incoming or outgoing mass relative to the c.o.m of the main body.
Yes, right. The force depends on how much you have to accelerate the gained mass, to be at the same speed as the original mass.
 
  • #9
HallsofIvy said:
If mass is changing rather than [itex]F= ma[/itex] use [itex]F= d(mv)/dt= m (dv/dt)+ (dm/dt)v= ma+ (dm/dt)v[itex].

This is quite widespread but erroneous idea, perhaps originating in the custom of writing Newton's second law in the form
$$
F=\frac{dp}{dt}.
$$
But this form is valid only for systems of constant mass. If the body considered loses parts so its mass is changing, the proper equation of motion for the center of mass of such changing body is
$$
F_{ext} + F_{exh} =m\frac{dv}{dt}
$$
where ##F_{ext}## is the usual external force (e.g. gravity) and ##F_{exh}## is the reaction force on the body due to the parts leaving it (e.g. exhaust gas). This equation has the form
$$
F=ma,
$$
not
$$F=dp/dt.
$$
In this sense, the formula ##F=ma## is actually more general than ##F = dp/dt##. We should therefore teach Newton's second law to students by always writing it in the form ##F=ma##. Not only is it more informative, but by appropriate choice of expression for the total force ##F##, applicable even to systems of variable mass.
 
  • #10
Delta² said:
Well maybe you are right hehe, at least those type of questions shouldn't put in written tests. It is just an extra term added though in Newton's Law familiar form F=ma.

The question would be quite a valid one if delivered verbally / interactively and more in the form of "Can you think of situations where N2 is not quite adequate for solving a problem". This could be followed by appropriate prompting and could provide an enlightening and fun session.

PS I wish contributors would make more of an effort to address questions on the level they were originally posed. This thread was about Introductory High School Science - in which Calculus is probably quite a stretch for most students. There is plenty of opportunity to show us what you know, elsewhere (big boys' threads). It makes things much more approachable for 'beginners' when they aren't swamped by high level content. I know I can also be guilty of this; it's a big temptation.
 
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  • #11
Jano L. said:
This is quite widespread but erroneous idea, perhaps originating in the custom of writing Newton's second law in the form
$$
F=\frac{dp}{dt}.
$$
But this form is valid only for systems of constant mass. If the body considered loses parts so its mass is changing, the proper equation of motion for the center of mass of such changing body is
$$
F_{ext} + F_{exh} =m\frac{dv}{dt}
$$
where ##F_{ext}## is the usual external force (e.g. gravity) and ##F_{exh}## is the reaction force on the body due to the parts leaving it (e.g. exhaust gas).

Jano, I think you're citing the same formula as Delta [tex]F=m\frac{dv}{dt}-v_{rel}\frac{dm}{dt}[/tex] except you've relabeled ##v_{rel}\frac{dm}{dt}## as ##F_{exh}##. I'm not sure if it is right to call ##v_{rel}\frac{dm}{dt}## a force. (I sincerely don't know.) If it's an external force of the lost/gained mass acting on the body's center of mass, then wouldn't you also include it in the term ##F_{ext}## when adding up the individual forces to obtain the net external force? If not, why not? Perhaps it's not an external force because there's only one m variable in the entire equation? Any guidance is appreciated.

Here's the article Wikipedia cites (worth reading the first half of the 2nd page): http://articles.adsabs.harvard.edu/full/seri/CeMDA/0053//0000227.000.html
 
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  • #12
high schoolphys said:
Jano, I think you're citing the same formula as Delta [tex]F=m\frac{dv}{dt}-v_{rel}\frac{dm}{dt}[/tex] except you've relabeled ##v_{rel}\frac{dm}{dt}## as ##F_{exh}##.

I meant a more general description, where direction of the leaving parts is not specified. Then the force due to departing parts may not be expressible in such a simple manner. The formula you refer to is applicable only to special case where the departing parts move in a direction opposite to the velocity of the body.

I'm not sure if it is right to call ##v_{rel}\frac{dm}{dt}## a force. (I sincerely don't know.) If it's an external force of the lost/gained mass acting on the body's center of mass, then wouldn't you also include it in the term ##F_{ext}## when adding up the individual forces to obtain the net external force? If not, why not? Perhaps it's not an external force because there's only one m variable in the entire equation? Any guidance is appreciated.

The equation of motion is meant for the motion of the center of mass of the remaining body. This remaining body is acted upon by two agents - the ordinary external force such as gravity or say, a pulling rope, and the force due to parts that have left the body. These parts are to be regarded as extraneous to the body so that no cancellation of force pairs occurs and non-zero net force due to the leaving parts is accounted for. This force is present only once in the equation of motion, of course. It would be a mistake to count it twice by including it to ##F_{ext}## and to ##F_{exh}##. If you wish, you may use different concept of external force, where ##F_{ext}## includes the force due to leaving parts and discard ##F_{exh}##.
 
  • #13
sophiecentaur said:
...PS I wish contributors would make more of an effort to address questions on the level they were originally posed. This thread was about Introductory High School Science - in which Calculus is probably quite a stretch for most students. There is plenty of opportunity to show us what you know, elsewhere (big boys' threads). It makes things much more approachable for 'beginners' when they aren't swamped by high level content. I know I can also be guilty of this; it's a big temptation.

+1 to that
 
  • #14
Jano L. said:
$$
F=\frac{dp}{dt}.
$$
But this form is valid only for systems of constant mass.

Is this just your personal opinion or can you proof it?
 
  • #15
DrStupid said:
Is this just your personal opinion or can you proof it?

I seem to remember a long thread about this topic a few months back.
 
  • #16
DrStupid said:
Is this just your personal opinion or can you proof it?

For systems of constant mass, the equation
$$
\mathbf F_{ext}=\frac{d\mathbf p}{dt}
$$
with ##\mathbf p =m\mathbf v## is generally valid because it is equivalent to ##\mathbf F_{ext}=m\mathbf a##, which we know is valid for such systems.

For systems of variable mass, the equation

$$
\mathbf F_{ext}=\frac{d\mathbf p}{dt}
$$
with ##\mathbf p =m\mathbf v## is generally invalid. Why? First, it does not take into account direction in which the leaving parts move. But this is important for the resulting motion. Also, this equation can be rewritten into form
$$
\mathbf F_{ext} = \frac{dm}{dt}\mathbf v + m\frac{d\mathbf v }{dt}
$$
which shows it is inconsistent with the Galilei relativity principle: the term ## \frac{dm}{dt}\mathbf v## depends on the frame of reference but the other terms do not. Furthermore, this equation leads to motion inconsistent with the law of conservation of momentum of isolated system. This law leads to the correct equation of motion
$$
\mathbf F_{ext} + \mathbf F_{exh} = m\frac{d\mathbf v}{dt}
$$
where ##\mathbf F_{ext}## is the force due to external bodies and ##\mathbf F_{exh} ## is the force due to leaving parts (exhaust gases in the case of a rocket).
 
  • #17
Jano L. said:
This law leads to the correct equation of motion
$$
\mathbf F_{ext} + \mathbf F_{exh} = m\frac{d\mathbf v}{dt}
$$
where ##\mathbf F_{ext}## is the force due to external bodies and ##\mathbf F_{exh} ## is the force due to leaving parts (exhaust gases in the case of a rocket).

I can't find it, now, but there was a long discussion about Newtonian physics as applied to variable-mass systems a few months ago. I think it's a very complicated subject, maybe too complicated to have a useful "law of motion".

Here's a scenario where I don't think your formula gives the correct answer, either.

Imagine you have an extended object, maybe a stick, or maybe a cigarette. With time, it's getting shorter, because one end is breaking off (or burning, or whatever). For simplicity, let the object be oriented in the y-direction, and assume that there are NO significant forces in the y-direction. There are no external forces at work, and the pieces that are breaking off or burning up just drop straight down (in the z-direction) without imparting any momentum to the remaining matter in the object.

So any equation of motion of the form F = ma would presumably tell you that there is no acceleration in the y-direction. But that might not be true. If by "the location" of the object, you mean the location of the center of mass, then the location is changing with time, because when pieces break off, the center of mass of the remaining matter shifts. The equation of motion governing this shift of center of mass would depend on the details of how the crumbling or burning is propagating, and would have nothing much to do with forces in the y-direction.
 
  • #18
stevendaryl said:
Imagine you have an extended object...

That's a problem with the extended object; the momentum law that Jano L cited applies to a point mass emitting another point mass. Within your extended object, any infinitesimal element will obey Newton's second law.
 
  • #19
Apparently there is a catch with stevendaryls example, that equation holds for extended objects like a rocket where c.o.m of rocket changes because they lose fuel mass due to their burning to produce exhaust gases.
 
  • #20
stevendaryl said:
So any equation of motion of the form F = ma would presumably tell you that there is no acceleration in the y-direction. But that might not be true. If by "the location" of the object, you mean the location of the center of mass, then the location is changing with time, because when pieces break off, the center of mass of the remaining matter shifts. The equation of motion governing this shift of center of mass would depend on the details of how the crumbling or burning is propagating, and would have nothing much to do with forces in the y-direction.

Interesting example. I did not think about such case, but I think now even here the equation applies. It is all about the meaning of ##\mathbf v##. The derivation of the equation introduces the quantity ##\mathbf v## as

$$
\mathbf v = \frac{\mathbf p}{m}
$$

where ##\mathbf p## is momentum of the remaining body and ##m## is mass of the remaining body. In your example with the cigarette, this ##\mathbf v## is constant so both sides of the equation of motion vanish.

I did said above that ##\mathbf v## in the equation is velocity of the center of mass of the remaining body. Your example shows that sometimes this meaning is not exactly the same as the one given by the definition above.

Luckily in rocket science, the difference is negligible, so we can use center of mass velocity in the equation without making too great an error :-)
 
  • #21
Now that I think about it, the equation of motion with variable ##m## can also be written in this funny way:

$$
\mathbf F_{ext} + \mathbf F_{exh} = m\frac{d}{dt}\left(\frac{\mathbf p}{m}\right).
$$
If ##m## is not constant, it cannot be canceled out:-)
 
  • #22
Jano L. said:
For systems of variable mass, the equation

$$
\mathbf F_{ext}=\frac{d\mathbf p}{dt}
$$
with ##\mathbf p =m\mathbf v## is generally invalid.

Is there a difference between ##F## and ##F_{ext}## or are you still talking about the same equation?
 
  • #23
DrStupid said:
Is there a difference between ##F## and ##F_{ext}##

I used ##F## as a wildcard for any of the relevant forces, total or external. No matter which of these is used, the equation
$$
force=dp/dt
$$
is not valid if mass changes. Then I used ##F_{ext}## for external force due to bodies other than the departed parts of the body in question and ##F_{exh}## for total force due to departed parts. Alternatively one may include forces due to these parts into ##F_{ext}## and discard the symbol ##F_{exh}##.
 
  • #24
Jano L. said:
Interesting example. I did not think about such case, but I think now even here the equation applies. It is all about the meaning of ##\mathbf v##. The derivation of the equation introduces the quantity ##\mathbf v## as

$$
\mathbf v = \frac{\mathbf p}{m}
$$

where ##\mathbf p## is momentum of the remaining body and ##m## is mass of the remaining body. In your example with the cigarette, this ##\mathbf v## is constant so both sides of the equation of motion vanish.

Yes, it's kind of an odd situation. Normally, in Newtonian mechanics,

[itex]\vec{P} = M \frac{d}{dt} \vec{R}[/itex]

where [itex]\vec{R}[/itex] is the position vector for the center of mass. But in the case of variable mass, the left side can be zero while the right side is non-zero.
 
  • #25
Hmmm, strange i can't find where the "catch" is but wikipedia explicitly states that v is the c.o.m velocity of the main body... Is wikipedia wrong in this case?

Update: I still think wikipedia is correct. We just have to distinct between the imaginary c.o.m and the material c.o.m. The material c.o.m has always zero velocity in stevendaryl's example.
 
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  • #26
Delta² said:
Hmmm, strange i can't find where the "catch" is but wikipedia explicitly states that v is the c.o.m velocity of the main body... Is wikipedia wrong in this case?

Update: I still think wikipedia is correct. We just have to distinct between the imaginary c.o.m and the material c.o.m. The material c.o.m has always zero velocity in stevendaryl's example.

Center of mass is usually defined as a geometrical point. If some parts are removed from one side of the body, its center of mass has to move. It appears that here the concept of center of mass is not that useful as for constant mass motion.
 
  • #27
Delta² said:
Hmmm, strange i can't find where the "catch" is but wikipedia explicitly states that v is the c.o.m velocity of the main body... Is wikipedia wrong in this case?

Update: I still think wikipedia is correct. We just have to distinct between the imaginary c.o.m and the material c.o.m. The material c.o.m has always zero velocity in stevendaryl's example.

Well, the definition of what mass constitutes the "object" is subjective. If I have a cigarette whose end is burning, it's my choice whether to consider the smoke and ash part of the cigarette, or not. If I include the smoke and ash, then the burning process doesn't change the center of mass. If I don't include the smoke and ash, then the burning process does change the center of mass.

This really shows why there is something a little fishy about variable mass problems. An object can only have a variable mass (classically, anyway) because we have drawn a completely subjective boundary between what counts as part of the object, and what doesn't. Since that boundary was the creation of our minds, there is really no reason for the boundary to obey any particular physical law for its propagation.
 
  • #28
Jano L. said:
Then I used ##F_{ext}## for external force due to bodies other than the departed parts of the body in question and ##F_{exh}## for total force due to departed parts.

Does that mean you changed your original statement in order to limit it to external forces? That would be acceptable.
 
  • #29
Jano L. said:
Center of mass is usually defined as a geometrical point. If some parts are removed from one side of the body, its center of mass has to move. It appears that here the concept of center of mass is not that useful as for constant mass motion.

In the case of mass variable systems, the geometric c.o.m does not always correspond (as time passes) to the same unique material point. The geometric c.o.m gains an extra velocity term due to the asymmetry in the way that new matter is lost (or gained). The material c.o.m (that is the point of matter that lies at the spatial coordinates defined by the geometric c.o.m) isn't aware of this asymmetry, its velocity is only due to F_ext+F_exh.

If we have constant mass or there is symmetry (like saying the stick is burning the exact same way from both edges) then the geometric c.o.m corresponds to a unique material point and its velocity equals the velocity of the material c.o.m.
 
  • #30
Delta² said:
In the case of mass variable systems, the geometric c.o.m does not always correspond (as time passes) to the same unique material point.
Yes, but this may happen already for systems which do not lose parts. Center of mass is a geometrical point. It does not matter which material point it coincides with. For some systems like a wedding ring the center of mass does not coincide with a material point at all.

If we have constant mass or there is symmetry (like saying the stick is burning the exact same way from both edges) then the geometric c.o.m corresponds to a unique material point and its velocity equals the velocity of the material c.o.m.

For given set of particles, there is only one commonly used concept of center of mass - average of constituents positions weighted by their mass:
$$
\mathbf r_{COM} = \frac{\sum m_k \mathbf r_k}{\sum_k m_k}.
$$
It is just an abstract point. There is no "material center of mass".
 
  • #31
Jano L. said:
It is just an abstract point. There is no "material center of mass".
And how do you refer to the point of matter that lies in the spatial coordinates of the geometric c.o.m? (there might be the case that there is no matter there but the usual case is that there is).

I ve to say, though i cannot prove it, my intuition tells me that the velocity of the material c.o.m (in the usual case it exists) and the geometric c.o.m is the same in all cases except in the case there is asymmetry in the way that mass is gained or lost.
 
  • #32
Delta² said:
And how do you refer to the point of matter that lies in the spatial coordinates of the geometric c.o.m? (there might be the case that there is no matter there but the usual case is that there is).

I do not know any special name for it. The material point is not important.

I ve to say, though i cannot prove it, my intuition tells me that the velocity of the material c.o.m (in the usual case it exists) and the geometric c.o.m is the same in all cases except in the case there is asymmetry in the way that mass is gained or lost.

That is true for rigid bodies. If the parts move with respect to each other, the center of mass of the body may move as well and is not attached to any particular mass point.
 

1. When does Newton's Second Law not hold?

Newton's Second Law does not hold when an object is either at rest or moving at a constant velocity. This is because the law specifically states that the acceleration of an object is directly proportional to the net force acting on it. If there is no net force, there can be no acceleration.

2. Does Newton's Second Law apply to all objects?

Yes, Newton's Second Law applies to all objects regardless of their size, shape, or composition. This law is a fundamental principle of classical mechanics and is used to describe the motion of all objects in the universe.

3. Can Newton's Second Law be applied to objects in outer space?

Yes, Newton's Second Law can be applied to objects in outer space as it is a universal law of motion. In fact, it was first developed to explain the motion of planets in our solar system.

4. Are there any exceptions to Newton's Second Law?

There are no known exceptions to Newton's Second Law. However, there are certain situations where the law may not be applicable, such as at the quantum level where other laws, such as the laws of quantum mechanics, take over.

5. Can Newton's Second Law be used to predict the exact motion of an object?

No, Newton's Second Law can only be used to predict the overall motion of an object. Other factors, such as air resistance and friction, can affect the exact motion of an object and must be taken into account for more precise predictions.

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