Uncertainty equal to zero

In summary, if you want to measure the momentum of a particle with complete certainty, you have to be able to find it and know its position at the same time. This is not possible with current technology, however it is theoretically possible.
  • #1
IWantToLearn
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could we able to measure the velocity for a free particle with uncertainty equal to zero, could we able to have a certain values for its velocity, and let the uncertainty of the position to be infinity

is there any theoretical restrictions on having a certain value for the velocity?
is there any practical restrictions?
 
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  • #2
If you have no idea where the particle is, how are you going to measure it?
 
  • #3
Vorde said:
If you have no idea where the particle is, how are you going to measure it?

that is means that, there have to be some uncertainty (not equal to zero and not equal to infinity) in the position to measure some uncertainty (not equal to zero and not equal to infinity) in velocity

and the bottom line is that we can't be have a measurement for velocity with zero uncertainty

am i right?
 
  • #4
IWantToLearn said:
and the bottom line is that we can't be have a measurement for velocity with zero uncertainty

Yes.

I think you have the right idea in the sentence before, but it's worded a little weirdly. Basically to be able to take any measurement of an object, you have to have some idea of where the object is, and that means you have a finite uncertainty in its position.
 
  • #5
yes the wording wasn't clear
it should be like that
"The bottom line is, we can't do a measurement for velocity with zero uncertainty"
 
  • #6
There is no theoretical limit to measuring momentum or position with complete certainty.
 
  • #7
DrChinese said:
There is no theoretical limit to measuring momentum or position with complete certainty.

But this will mean that the particle has a single value of velocity, there is no distribution whatsoever of this velocity, this would be a particle that has a single value of momentum or in the wave aspect a plane wave that fills the whole universe, a particle that exist by the same probability in everywhere in the universe.
When we solve Schrodinger equation in the time independent case for a free particle we would get a solution that is a plane wave with a definite momentum..A e^_{ixp/h} but this solution is not normalized, or in other words, the sum of probabilities of finding the particle somewhere is not one but infinite
the free particle with one single value of velocity or momentum is a myth that does not exist.
 
  • #8
IWantToLearn said:
But this will mean that the particle has a single value of velocity, there is no distribution whatsoever of this velocity, this would be a particle that has a single value of momentum or in the wave aspect a plane wave that fills the whole universe, a particle that exist by the same probability in everywhere in the universe.

Not necessarily that it is equally likely to be anywhere, but certainly a wide range of source positions. That is the wave picture.
 
  • #9
DrChinese said:
There is no theoretical limit to measuring momentum or position with complete certainty.

This is at least an overstatement, right? I make a local measurement of a particle's momentum, then the position is certainly bound by a light cone for a given time afterwards. Doesn't this imply a lower bound on my initial momentum measurement?
 
  • #10
king vitamin said:
This is at least an overstatement, right? I make a local measurement of a particle's momentum, then the position is certainly bound by a light cone for a given time afterwards. Doesn't this imply a lower bound on my initial momentum measurement?

Not sure I see that. When you specify how are making the measurement, I think it will be clear that the limits are experimental/practical - not theoretical.

IMPORTANT NOTE: Of course when I say there are no theoretical limits to measuring momentum or position with complete certainty, I do NOT mean they can be determined at the same time. It is often restated as follows:

There are no theoretical limits to preparing a particle in a certain eigenstate of momentum or position with complete certainty, however it cannot be in a certain eigenstate of both momentum or position at the same time.
 
  • #11
Yes, in principle we can measure the velocity (actually we prefer to use momentum, ie mass times velocity) with complete certainty.

is there any theoretical restrictions on having a certain value for the velocity?

In theory, no. The only downside is that by measuring the momentum to a perfect accuracy, we lose complete knowledge of it's position. Ofcourse that means, that the particle, whose momentum you measured, is effectively at "nowhere".

is there any practical restrictions?

Yes and quite severe ones. The only waveform with a single frequency (and wavelength) is an infinite plane-wave. Such a thing cannot exist in reality since it would span from infinity to infinity. Now because of the particle-wave duality, your particle, whose velocity you measure with complete certainty, would collapse into such a state, which is impossible. From this we can deduce that in practice, you cannot achieve such accuracy no matter how well you design your apparatus.
 
  • #12
Thoros said:
Yes, in principle we can measure the velocity (actually we prefer to use momentum, ie mass times velocity) with complete certainty.
In theory, no. The only downside is that by measuring the momentum to a perfect accuracy, we lose complete knowledge of it's position. Ofcourse that means, that the particle, whose momentum you measured, is effectively at "nowhere".

it is like you are saying that mathematically it is possible to measure the momentum with zero uncertainty , but in physics this is impossible

saying that the free particle is never exist is much like saying that nature refuse a complete certainty for a measurement of the momentum or the position

so i can say that (a measurement with a complete certainty is impossible and "this is an inherited feature in nature")
 
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  • #13
IWantToLearn said:
it is like you are saying that mathematically it is possible to measure the momentum with zero uncertainty , but in physics this is impossible

saying that the free particle is never exist is much like saying that nature refuse a complete certainty for a measurement of the momentum or the position

so i can say that (a measurement with a complete certainty is impossible and "this is an inherited feature in nature")

I think you are confused about matters of principle and what can be done in practice. In practice it is impossible to know any real number with 100% accuracy because that would involve an infinite decimal expansion but in principle QM allows position and momentum to be measured to any degree of accuracy - just not simultaneously.

Thanks
Bill
 
  • #14
bhobba said:
I think you are confused about matters of principle and what can be done in practice. In practice it is impossible to know any real number with 100% accuracy because that would involve an infinite decimal expansion but in principle QM allows position and momentum to be measured to any degree of accuracy - just not simultaneously.

Thanks
Bill

i understand that the uncertainty principle prevent us from doing a measurement with complete certainty for pairs of physical quantities (position and momentum) (energy and time) and that there is some kind of trade off in the uncertainty of the measurement for each quantity of them

Ok, now this is not my point

my point is regardless of any technological advances or accurate measurements, i claim that to have a complete certainty, this means that we have a free particle, exist in all of the universe with the same probability everywhere and not affected by any field
in my view this is a myth
since the universe is a grand field full of potentialities, and in fact there is no meaning for the term nothing, because always there is something, so our particle will never be free
so no complete certainty even theoretically

this is my claim, correct me of i am mistaken
 
  • #15
A free particle, like knowing position exactly, is a conceptualization, an idealization pertaining to a particle in an inertial frame. Even in deepest space an exact inertial frame does not exist but as a conceptualization is very valuable. It is similar to a point being defined as having position and no size - such does not exist either but as a way of stripping away the inessential and getting to the heart of what a point is it is vital.

Thanks
Bill
 
  • #16
IWantToLearn said:
it is like you are saying that mathematically it is possible to measure the momentum with zero uncertainty , but in physics this is impossible

saying that the free particle is never exist is much like saying that nature refuse a complete certainty for a measurement of the momentum or the position

so i can say that (a measurement with a complete certainty is impossible and "this is an inherited feature in nature")

"nature abhors infinitey" - in this case infinite precision - might be the general principle...
 
  • #17
IWantToLearn said:
my point is regardless of any technological advances or accurate measurements, i claim that to have a complete certainty, this means that we have a free particle, exist in all of the universe with the same probability everywhere and not affected by any field

If i understand you correctly, you are right. The free particle with definite momentum will be spread across the universe with the same probabilty amplitude. This is the infinite plane-wave that exists everywhere simultaneously.

IWantToLearn said:
in my view this is a myth
since the universe is a grand field full of potentialities, and in fact there is no meaning for the term nothing, because always there is something, so our particle will never be free
so no complete certainty even theoretically

Now, you are right, it is a myth, but the simplest answer would be this: Any real physical solution to the Schrödinger equation must be normalizable. An infinite plane-wave is NOT normalizable. You can check it yourself by trying to normalize a sin function that spans infinity.

So to conclude: a free particle with definite energy (energy and momentum for a free particle are the same thing) cannot exist.

PS: Just to be clear why the position and momentum behave as such. They are infact the same thing in principle. They are related by a Fourier transform. Therefore knowing the momentum means knowing the position. But in Quantum Mechanics, all you can know, is the probability distribution. And this is what we have been talking about.

In this example, your distribution of momentum would be a delta function. The Fourier transform of a delta function, that is the distribution of position, would in turn be a constant across space. And vice versa.

And just to make sure i don't leave room for misunderstandings: As I've said, we only know probabilities that an experiment will give some real result. To know the momentum to an absolute accuracy, you would have to conduct the experiment on an identical particle in identical situations a lot of times (essentially infinite experiments to know it at 100% accuracy). But no matter how hard you try, your results will be spread out a little. For reasons I've already tried to explain.
 
  • #18
Thoros said:
Now, you are right, it is a myth, but the simplest answer would be this: Any real physical solution to the Schrödinger equation must be normalizable. An infinite plane-wave is NOT normalizable. You can check it yourself by trying to normalize a sin function that spans infinity.

That is true - it is a myth - but if it is normalizable or not depends on the formalism you are working with - in the Rigged Hilbert Space formulation it can be accommodated.

Thanks
Bill
 
  • #19
I think you can normalize a sin wave in a finite universe. We are nitpicking over what means theoretically possible here. If we remove all matter from the universe except for a single particle there could be a nice plain wave kind of function inside, but as far as we know it is impossible to remove matter from the universe. There are all kinds of mathematical statements that are a bit fuzzy on the edges when applied to physics, like translation invariance. Nothing is translation invariant as long as Alpha Centauri is still a star and not part of some homogenous space goo, but momentum conservation is still true. We split the world into the part that is theory and the part that is the random fact how matter seems to be distributed, and how the universe is curved and so on. In this spirit there is no theoretical limit to momentum measurements. (And btw from the definition of limits if you cannot measure something with infinite precision it doesn't mean there is a limit. Just like you cannot state the largest natural number.)
 
  • #20
The uncertainty relation is between position and momentum. You may be able to measure the momentum of the particle by measuring the force it imparts on a rigid wall, or in a scattering experiment.
 
  • #21
0xDEADBEEF said:
(And btw from the definition of limits if you cannot measure something with infinite precision it doesn't mean there is a limit. Just like you cannot state the largest natural number.)

for me
the concept of infinite precision = the concept of infinity
you could always try but you can never reach to an end
 
  • #22
Hmmm... but if you know the position with precision, then the momentum uncertainty is infinite, which DOES NOT equal Planck's constant.
 
  • #23
StevieTNZ said:
Hmmm... but if you know the position with precision, then the momentum uncertainty is infinite, which DOES NOT equal Planck's constant.

You will never know the position with infinite precision, so you will never get infinite momentum.
 
  • #24
Drakkith said:
You will never know the position with infinite precision, so you will never get infinite momentum.

But with zero uncertainty in momentum or position, you have infinite uncertainity with the other observable. So why would there not be a limit on how accurate/precise the position etc can be known?
 
  • #25
StevieTNZ said:
But with zero uncertainty in momentum or position, you have infinite uncertainity with the other observable. So why would there not be a limit on how accurate/precise the position etc can be known?

If your limit is infinity, or in this case zero, is that really even a limit? And as I said, we can never get the uncertainty in a measurement down to zero. It isn't possible. And I think we can measure both the momentum AND position of a single particle with any degree of accuracy we want down to the physical limits of our detectors, it's just that we can't predict what it's position and momentum will be after the measurement, or what multiple identically prepared particles will have for their position and momentum. Someone correct me if that's wrong.
 
  • #26
Drakkith said:
If your limit is infinity, or in this case zero, is that really even a limit? And as I said, we can never get the uncertainty in a measurement down to zero. It isn't possible. And I think we can measure both the momentum AND position of a single particle with any degree of accuracy we want down to the physical limits of our detectors, it's just that we can't predict what it's position and momentum will be after the measurement, or what multiple identically prepared particles will have for their position and momentum. Someone correct me if that's wrong.

It's my understanding, and this is (I believe) in agreement with your last statement, is that we can make any individual measurement to an arbitrary accuracy, but when you take multiple measurements of the same thing (or measure different things that 'should' be in the exact same state) you'll get a span of results with the standard deviation of those results obeying the uncertainty principle.
 
  • #27
Contrary to Dr Chinese's post #10 [ you can't make simultaneous measurements to arbitrary accuracy] others here say 'oh yes you can':

[I'm not saying if either view is correct or not, only that there seem to be different interpretations. Pay close attention to any further posts by Dr. Chinese as he has proven a very valuable commentator here. ]

See this current discussion beginning with my post #11, page 1:

[quotes from other 'experts' in these forums]:

HUP in QFT and QM:virtual particles

https://www.physicsforums.com/showthread.php?t=650492

The essence of the different viewpoints, is I believe, this:

The HUP isn't about the knowledge of the conjugate observables of a single particle in a single measurement. The uncertainty theorem is about the statistical distribution of the results of future measurements. The theorem doesn't say anything about whether you can measure both at the same time. That is a separate issue.
Read my later posts in the above link for sources and complete discussions of my posted quotes...I'll be away for a month so won't be back for this incarnation of HUP!
 
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  • #28
Just to add to what Naty1 says above (and I don't think he or I have any disagreement on this at all): Here is what he quoted ZapperZ as saying in the thread he referenced:

"...the HUP isn't about the knowledge of the conjugate observables of a single particle in a single measurement. ... there's nothing to prevent anyone from knowing both the position and momentum of a particle in a single measurement with arbitrary accuracy that is limited only by our technology. However, physics involves the ability to make a dynamical model that allows us to predict when and where things are going to occur in the future. While classical mechanics does not prohibit us from making as accurate of a prediction as we want, QM does!"

I did not say this as well in my #10, but I was trying to say: Although HUP is usually discussed as limiting our ability to observe certain properties, it does in fact limit our ability to prepare a system in a state with certain properties. If you say that these are the same thing, that is fine too.

The issue is readily seen with entangled particle pairs. You can measure each for a different non-commuting property. So you might think you would know (by inference) the value of non-commuting observables simultaneously. But subsequent tests of those particles will not support that inference.
 

1. What does "uncertainty equal to zero" mean?

Uncertainty equal to zero refers to a situation where there is no variability or error in a measurement or result. It means that the value obtained is considered to be exact and there is no range of possible values.

2. Is it possible for uncertainty to be equal to zero?

In theory, yes, it is possible for uncertainty to be equal to zero. However, in practice, it is very rare to have a measurement or result with absolutely no uncertainty. There is always some degree of error or variability present.

3. How is uncertainty equal to zero calculated?

Uncertainty equal to zero is not calculated, but rather it is determined by the precision and accuracy of the measurement or result. If a measurement is highly precise and accurate, the uncertainty may be very small and close to zero.

4. What are the implications of uncertainty equal to zero?

Uncertainty equal to zero means that the result or measurement is considered to be exact and there is no room for error. This has implications for the reliability and validity of the data, as well as the confidence level in the conclusions drawn from it.

5. How does uncertainty equal to zero impact scientific research?

In scientific research, uncertainty equal to zero is often seen as an ideal situation, but it is rarely achieved. It is important to acknowledge and account for any uncertainty in measurements and results to ensure the validity and accuracy of the research findings.

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