What is the Heisenberg Uncertainty Principle? - Chad Orzel

Adds a whole new meaning to the phrase, "I see your point, but I don't know where you're going with it."

I have a much simpler and shorter explanation for the Uncertainty Principle:
Imagine a car moving along a road. If you want to see the exact place where the car is, you must pause time (because it's always moving). You pause time, and you mark its place. While you paused (imagine it like a photo), you CAN'T know its speed. It's a picture. If you want to find out the speed, you must unpause and measure it. But if you unpause, it's impossible to know the exact position of the car because it's changing...
EDIT: Because many people cannot understand that if you put a speed-o-meter in a car you still measure the velocity in an interval and not in a point, imagine it like a video that you pause it and unpause it. You cannot interact with the car to put a speed-o-meter of some sort, because if you do, this is not the same example.
EDIT2 (Years later): Some people are getting confused by the term velocity. A stationary object has 0 velocity in relation to its surroundings. A video shows a moving object that therefore has velocity. A photograph shows a stationary object.

Me to my brain: "Got it?"
My brain: "Never ever dare to show me this again."

"The only thing we are absolutely certain about is that nothing is certain."
-Werner Heisenberg

Heisenberg and Schroedinger are in a car that gets stopped by the police.
Policeman."Do you know you were doing 75mph?"
Heisenberg. "Oh great, now we're lost!"
Cop is not happy, checks the boot/trunk of the car.
Cop. "There is a dead cat in here!"
Schroedinger. "Well, there is NOW!"

When I'm feeling smart I come here to watch videos and get rid of that nonsense feeling.

They named it the Uncertainty Principle because no one knew what Heisenberg was talking about.

"Say my name"
"Uncertainty Principle"
"You're Goddamn right."

You never know when it's Walter White and when Heisenberg kicks in. That's the real Heisenberg uncertainty principle.

I came here to learn. After watching the video, the only thing i've learned is im dumb.

Say my principle!
I don't know it
SAY IT!
Heisenberg's uncertainty principle
You're God Damn Right!

This is the moment Werner became Heisenberg...

Simplify the explanation, you lose the finer details... Elaborate the details, the explanation becomes too complicated...
This is Heisenberg Uncertainty Principle

One of my favorite jokes from Futurama
*Prof. Farnsworth is at a horse race*
The announcer declares, "And the winner is number 3, in a quantum finish!"
The Professor angrily shouts -- "No fair you changed the outcome by measuring it!"

Hats off to scientists, who have to deal with all this complex stuff, So that humanity can advance .

A cop stops Heisenberg for speeding and asks him "Do you know how fast you were going?". He replies "No, but I know where I am".

cop: how fast you were going on this road
me: let me tell you a story.....

I've heard someone describe it as,
"We know the past, we know the future, but time is always moving, and the present is just the nearest past that we can grasp."

I'm uncertain of my understanding of the uncertainty principle

That went from 0 to 100 really quickly.

I took quantum chemistry in college. Long story short: I had to seduce my professor.

*cop pulls over heisenberg* Cop: Do you know how fast you were going?! Heisenberg: No, but I know where I was! Hahahahahaha

TED-ED, you guys have great animation with great narration, but, I can't understand anything 😂

This is the moment that Walt became Heisenberg.

Makes more sense why Breaking Bad used the name. The uncertainty of where Walt was in terms of his mindset, morality and motives.

The Tuco "confused anger" principal is when you watch a science video and get angry because youre lost 30 seconds in to the video.

1:13 that transition was amazing

Heisenberg's principle: "I am the one who knocks".

WOW! This totally blew my mind! I never realized that the uncertainty principal was related to wave particle duality in any way. This FINALLY makes sense. Thank you!

That was so cool! Although it’s hard to think of the myriad of properties a material can have, with a name like the Uncertainty Principle. It sounds more like a restriction, on surface level, of being able to know either one or the other, the momentum of an object, or the position. But as you dive deeper, you begin to appreciate and embrace the Uncertainty, which is, at quantum level, not much different from the uncertainties you and I face every day.
Fantastic video, btw!

What a great explanation! I am a firm believer that no matter the complexity of an idea, it could be broken down into simple ideas or arithmetic operations.
Don't ever let the complexity of a subject or a field overwhelm you. Keep learning.

Mate you give an aspirin a headache....

Finally! I understood this amazing topic after soo many years!!

Most awesome explanation ever recieved about heisenberg uncertainty principle because everybody who taught me misleaded me into believing this as a limit of practical precision but i always felt something wrong in that. Now it is crystal clear and i am very satisfied and happy about it. Thanks sir !

Let's say you try taking a photograph of a moving car. Say it takes your camera a tenth of a second to get the photo. What you will see is a (short) blur of the car. If you measure the length of the motion blur you can find out how fast the car was going. But you can't say where exactly the car is. The car was in all the places the blur is while you were taking the photo. Now suppose you take a perfect instantaneous picture. You know exactly where the car is. But can you even tell if it's moving at all? :D

Electron: exists
Human: saw it
Electron : Well now I don't want to be an electron

Heisenberg uncertainty principle is not knowing who knocks the door..

Heisenberg made a lot of good science. Too bad he threw it all away when he started cooking meth.

This is the absolute best explaination I’ve ever heard of the Heisenberg Uncertainty Principle. If you didnt get it then forget taking up a career in Physics!

Heisenberg's uncertainty principle: Δх * Δр ≥ ħ/2
The Heisenberg's uncertainty principle is correct, moreover, it is fundamental. If the uncertainty principle is incorrect, then all quantum mechanics is incorrect. Heisenberg's justified the ncertainty principle in order to save quantum mechanics. He understood that if it is possible to measure with every accuracy both the coordinate and momentum of a microparticle, then quantum mechanics will collapse, and therefore further justification was already a technical issue. It is the uncertainty principle that prohibits microparticles in quantum mechanics from having a trajectory. If the coordinates of the electron are measured at definite time intervals Δt, then their results do not lie on some smooth curve. On the contrary, the more accurately the measurements are made, the more "jumpy", chaotic the results will be. A smooth trajectory can only be obtained if the measurement accuracy is small, for example, the trajectory of an electron in a Wilson chamber (the width of the trajectory is enormous compared to the microworld, so the accuracy is small).
Heisenberg's formulated the uncertainty principle thus:
if you are studying a body and you are able to determine the x-component of a pulse with an uncertainty Δp, then you can not simultaneously determine the coordinate x of the body with an accuracy greater than Δx = h / Δp.
Here is a more general formulation of the principle of uncertainty: it is impossible to arrange in any way an instrument that determines which of the two mutually exclusive events has occurred, without the interference pattern being destroyed.
It should be immediately said that the Heisenberg uncertainty principle inevitably follows from the particle-wave nature of microparticles (there is a corpuscular-wave dualism is the principle of uncertainty, there is no corpuscle-wave dualism - there is no uncertainty principle, and in principle quantum mechanics, too). Therefore, there is an exact quantitative analogy between the Heisenberg uncertainty relation and the properties of waves.
Consider a time-varying signal, for example, a sound wave. It is pointless to talk about the frequency spectrum of the signal at any point in time. To accurately determine the frequency, it is necessary to observe the signal for some time, thus losing the accuracy of time determination. In other words, sound can not simultaneously have the exact value of its fixation time, as it has a very short pulse, and the exact frequency value, as it is for a continuous (and, in principle, infinitely long) pure tone (pure sine wave). The time position and frequency of the wave are mathematically completely analogous to the coordinate and (quantum-mechanical) momentum of the particle.
We also need to clearly understand that the Heisenberg's uncertainty principle practically prohibits predicting behavior (in the classical sense, since Newton was able to predict the position of the planets), for example, an electron in the future. This means that if the electron is in a state described by the most complete way possible in quantum mechanics, then its behavior at the following moments is fundamentally ambiguous. Therefore, quantum mechanics can not make strict predictions (in the classical sense). The task of quantum mechanics consists only in determining the probability of obtaining a particular result in the measurement, and this is fundamental. That is why the uncertainty principle has such a fundamental meaning (there is no uncertainty principle - there is no quantum mechanics). But this does not mean that we do not know any "laws or variables that are hidden from us", etc. No. It's just the reality. This is analogous to how a particle can exhibit corpuscular and wave properties - just this is reality and nothing more. And even if we know the "hidden parameters" (compare, understand why the wave properties and corpuscular ones are manifested), this reality will not change, and the uncertainty principle will also work, but we will understand it more fully.
It must be added that not all physical quantities in quantum mechanics are measurable simultaneously, that is, they can have simultaneously definite values. If physical quantities can simultaneously have definite values, then in quantum mechanics they say that their operators commute. The sets of such physical quantities (complete sets) that have simultaneously defined values are remarkable in that no other physical quantity (not being their function) can have a definite value in this state. The fully described states (for example, the description of the electron state) in quantum mechanics arise as a result of the simultaneous measurement of a complete set of physical quantities. By results of such measurement it is possible to determine the probability of the results of subsequent measurements, regardless of what happened with the electron before the first measurement.
If physical quantities can not simultaneously have definite values, then their operators do not commute. The Heisenberg uncertainty principle establishes the limit of the accuracy of the simultaneous determination of a pair of physical quantities that are not described by commuting operators (for example, coordinates and momentum, current and voltage, electric and magnetic fields).
Let's add a little history. A. Einstein assumed that there are hidden variables in quantum mechanics that underlie the observed probabilities. He did not like the principle of uncertainty, and his discussions with N. Bohr and W. Heisenberg greatly influenced quantum mechanics and science as a whole.
In the Copenhagen interpretation of quantum mechanics (N. Bohr and followers), the uncertainty principle is adopted at the elementary level, and it is in this interpretation that it is believed that this can not be predicted at all by any method. And it was this interpretation that Einstein questioned when he wrote to Max Born: "God does not play dice." To which Niels Bohr, answered: "Einstein, do not tell to God what to do." Einstein was convinced that this interpretation was erroneous. His reasoning was based on the fact that all the already known probability distributions were the result of deterministic events. The distribution of the tossed coin or rolling bone can be described by the probability distribution (50% eagle, 50% tails). But this does not mean that their physical movements are unpredictable. Conventional mechanics can calculate exactly how each coin will land, if the forces acting on it are known, and the eagles / tails will still be randomly distributed (with random initial forces). But it is unlikely that this experience can be extended to quantum mechanics.
The position of Bohr and Einstein must be viewed as views from different angles of view on one phenomenon (problem), and in the end it may turn out that they are right together. This can be demonstrated by lottery. Despite the fact that theoretically the results of the lottery can be predicted uniquely by the laws of classical mechanics, knowing all the initial conditions (it is necessary only to determine all the forces and perturbations, and to make the necessary calculations), in practice the lottery results are always probabilistic, and only in theory they can be predicted (try win the jackpot :). Even in this simplest case, we will be "inaccessible" to all the initial data for calculations. It is logical to assume that the quantum system will be incomparably more complicated than the lottery, and therefore, if we master the "true" laws of the quantum world, the probabilistic picture will remain, since the microworld is such in essence. Moreover, if you think about it, then our world is also probabilistic. It is deterministic only in theory, and practically, in everyday life, we can only predict, for example, tomorrow (or a second, or a year, or 10 years) with a certain probability (who can guarantee the event of tomorrow with 100% probability?). And what is interesting is that only after having lived it (by making a measurement), we can say what probability was realized. Quantum mechanics in action :).
More see by link: www.quora.com/Is-Heisenbergs-principle-of-uncertainty-wrong/answer/Volodymyr-Bezverkhniy?share=b4884212
Benzene on the basis of the three-electron bond:
REVIEW. Benzene on the basis of the three-electron bond (full version, 93 p.).
vixra.org/pdf/1612.0018v5.pdf
1. Structure of the benzene molecule on the basis of the three-electron bond.
vixra.org/pdf/1606.0152v1.pdf
2. Experimental confirmation of the existence of the three-electron bond and theoretical basis ot its existence.
vixra.org/pdf/1606.0151v2.pdf
3. A short analysis of chemical bonds.
vixra.org/pdf/1606.0149v2.pdf
4. Supplement to the theoretical justification of existence of the three-electron bond.
vixra.org/pdf/1606.0150v2.pdf
5. Theory of three-electrone bond in the four works with brief comments.
vixra.org/pdf/1607.0022v2.pdf
6. REVIEW. Benzene on the basis of the three-electron bond (full version, 93 p.). vixra.org/pdf/1612.0018v5.pdf
7. Quantum-mechanical aspects of the L. Pauling's resonance theory.
vixra.org/pdf/1702.0333v2.pdf
8. Quantum-mechanical analysis of the MO method and VB method from the position of PQS.
vixra.org/pdf/1704.0068v1.pdf
Bezverkhniy Volodymyr (viXra):vixra.org/author/bezverkhniy_volodymyr_dmytrovych
Свернуть
ОТВЕТИТЬ

How can I use this to defend my speeding ticket?

Adds ammunition to the saying "Those who claim to understand quantum theory don't understand quantum theory". It's a strange world.

Now, say my principle's name.

This was 91.96 % pure

In my college, sir explained this with the help of a ceiling fan. He told us to look at the fans blade when he switched on/off the fan.
Particle nature : when it is switched off
Wave nature : when it is switched on

This is a much better (yet still a bit hard to follow) explanation of Heisenberg Uncertainty Principle than the ones that I've read before.

This is well done. Thanks for explaining this properly rather than just giving the Heisenberg uncertainty principle formula and saying that is how it works.

Thank you!!
I have watched many videos, had gone to all the lectures of my uni ( the number one uni in the country lol) and only understood this now!
Much blessings and love on your way!

I was taught that principle when I was in senior high school. It still amazes me. Thanks

This is one of the best explanations I've found on UA-cam.
Great job Ted-Ed!

"Say my name."
"I'm not sure."
"You're goddamn right."

The only thing I got from that video is that uncertainty doesn't come from the measuring devices, but from the particle itself.

U explaind it 1000 times better than how's its explained to us in 11th class in india. Well done!!

@3:52 Just to double check that "bigger momentum uncertainty", actually means "bigger value of the momentum uncertainty". Meaning, the momentum becomes more defined, rather than becoming more "uncertain", and thus in fact, "less uncertain" = "more certain". After all, we are reducing the "position uncertainty" value, which means we would be increasing the "momentum uncertainty" value. Fantastic video! Thank you.

every time I have a test I always watch this video again and again..... It's helps me in clearing my concepts

What is Heisenberg's uncertainty principle?
I'm not sure.

I must appreciate the crystal clear voice 👍👍👍

I thought we were going to learn about making meth
..edit; wow a 1000 likes i am very humbled thanks i am glad you enjoyed the joke

YEAH MR. WHITE, YEAH SCIENCE!

Well, one thing is certain: this explanation went over my head. ;)

Mom : "what are you watching?"
Me : "the Heisenberg uncertainty principle."
Mom : "so what is it?"
Me : "......"

"It a quantum finish!"
"NO FAIR! You changed the outcome by measuring it!"

Amazing video! its difficult to explain that concept but in my opinion you made a great video for that :)

very simply explained-thank you!

From this day on whenever I start feeling smart I'll come back to this video to remind myself that I'm actually quite stupid in some areas.

One of the best explanation for the uncertainty rule of Heisenberg out there .Means alot.❤✌

I wanted to learn how to manufacture methamphetamine in a RV, but this is also cool for me.

This was so helpful, I didn’t know momenthum and position were related to wave and particle nature. Thanks a lot!!

"Jesse, where's my TED Talk?"

My favorite interpretation is that objects (including photons) literally don't have position and momentum at the same time. Everything moves as a wave, but arrives as a particle. The level of observer necessary to collapse the wave into a particle is anything; when one object "hits" any other object, the wave becomes a particle.

I clicked because I thought this was insight into the life and dealings of Walter White. Not totally disappointed.

this is a great and understanding explanation.

Friend: hey particle where you going, where can we meet up.
Particle. Hehe can’t tell you both 😉

"Who came up with the uncertainty principle?"
-"Heisenberg"
"You're god-damn right"

I wrote notes and followed each line and the animation,it make my life simpler

This is the exact moment the Uncertainty Principle becomes Heisenberg.

You guys always impress me ..... How do you simply those complicated stuffs, they are super cool.

My chemistry was doing a powerpoint presentation of this. But instead of putting Heisenberg's picture, he put Walters's picture in the powerpoint.

Very well presented, even for us non-scientist types. Thanks.

TED ED always amaze us with great animation and precise explanation!

3 thank you's are in order
1. Google for recommending this
2. Chad Orzel for making this, just brilliant!
3. Dethneko, best comment ever.

Came here solely for Breaking Bad references.

I saw heisenberg and I clicked on the video

to elaborate further on the point i just made. An object CAN'T be a particle and a wave at the same time. It means that not only we have uncertainty measuring both position and momentum at the same time, but actually, when we measure an object's position, then this object doesn't have any momentum at this particular time. same goes the other way around. when we are measuring an object's momentum, then this object doesn't have a position at this particular time. and that's because a particle and a wave or a position and a momentum doesn't meet/exist at the same time..

“I am the danger!” - Heisenberg

Suddenly it makes a whole lot of sense, cheers! :)

I didn't learn anything from this TedEd. Please someone needs to see to this. Thanks.

I had to watch this video so many times to understand it...

whenever mankind breaks new horizon in knowledge and understanding his surrounding, i feel that mankind will never know everything in this earth

Great explanation; This is what can happen with a combination of an artist and a teacher..

I think i get but then again.......

Watched
Still know nothing

im studying about this currently...n this is video is so helpful...the animation is really easy to understand n interpret, the vocabulary used n the explanation.. everything is so easy to understand n learn... thankyou so much 💜💜

This guy just finished reading the NCERT, Indians.... ASSEMBLE

Heisenberg, you know, he's the one who knocks

Great now I can help tutor my peers in chemistry and physics class!

Simply put: you can’t measure the exact position and velocity of a subatomic particle at the same time because while you r measuring it, the act of measuring would already have changed the position or velocity of said subatomic particle, rendering it impossible to know its original position or velocity. Why the subatomic particle behaves as such is because it exists in state of probability rather certainty.

This is kind of like that one show where that one dude breaks bad

This is my simple interpretation of uncertainty principle for ordinary people:
When a thing gets very very small. It is no longer a thing. Since it is not a thing, you can’t tell precisely where or how fast it is. But how small a thing needs to get before it is no longer a thing, this is the formula…

i learned about this alot, but dont really know how it changes my life