What is Quantum Tunneling, Exactly?

The humility you bring to these videos where you're willing to ask for explanations and admit what isn't your forte is really inspiring and makes some pretty esoteric stuff a lot more approachable.

“Unlike a ball, we can’t pinpoint exactly where an electron is.”
Wow, balls must be really good at physics to be able to pinpoint exactly where an electron is.

Cats are inherently non-classical objects [1]. My cat can move through a closed cat door, but he never does so when I'm there observing him (he just meows for me to open the cat door). Is it possible that he has harnessed quantum tunneling?
[1] Schrödinger, 1935

3:45 that got intense real quick

Video: evanscent
My brain:
wake me up! wake me up inside!

I think quantum field theory might help with intuition. Instead of thinking in terms of particle vs wave you can view everything as disturbances in fields. This means that particle behavior arises from interacting perturbations in fields and the interactions of different “particles” or a complicated multiple perturbation event can create a field effect without the particle seeming to cross that distance.
Really the move from thinking of particles and waves to considering fields was a huge moment for me!

That electron doesn't look very happy.
Oh well, he's just being negative.

Just here to watch the video and see if this channel is at a million subs yet. No...alright will check back next week.

Pleased to meet you. Welcome to the Tom Scott Effect!

I think I suffer from 'frustrated total internal reflection'...

It was harder for me to pretend the pencil was a straw then understand Quantum Tunneling

So, there's a miniscule probability that some Quantum Mechanics concepts will tunnel into my ape brain? Too bad they are evanescent :(

This is the best hidden gem of a channel I've ever found:)

I've often heard that quantum tunneling 'sometimes happens' when the energy potentials make it possible, but not about the evanescent wave function. I'm very glad to have learned something today. Thank you so much for taking it a couple steps beyond what is so often repeated, while keeping the math accessible to non-physicists.

I love your honesty and references to previous videos, it shows you analyse past experiences, take on board feedback and aim to create a more efficient future with more understanding examples 😊

Thank you for this. I've never encountered a description of quantum tunneling that made the remotest bit of sense to me. This gave me what I can comfortably say is a vague understanding, which, considering it's quantum physics, is high praise :)

Tunneling is also a term in game/physics engines which describes when collisions are missed because the simulated objects are too small and too fast. It's a result of simulating things in discrete timesteps (two objects might only be colliding for half a timestep), and I think it's named after quantum tunneling.

I love your videos.
That's it. That's all I have to say. I can't think of any compliments that do this video justice.

Jade, you asked for an explanation to evanescent wave decay. A good example is to look at ocean waves. Near the surface a measurement of the hydrostatic pressure varies in proportion to the varying wave height above the point of measurement. As the point of measurement goes deeper that point is no longer merely affected by the wave directly above it but by the combined effect of waves to either side of vertical. Assuming the waves are sinusoidal the average effect upon the variation of hydrostatic pressure tends to diminish as the contribution of multiple peaks will tend to cancel the contribution of multiple troughs. There is also a diminishing effect as you get farther from the wave due to depth (I suspect proportional to 1/r where r is the distance to the wave). There is a formula which describes the variation in hydrostatic pressure due to the waves as a function of depth, and lo and behold just as in the case of the evanascent wave that variation decays exponentialy. I am a retired sonar engineer, and this problem came up in the course of my work.

I may know why that drop of light occurs. Like when we throw a ball on floor it reflects. In this process it losses very little kinetic energy to floor . Thats why we feel vibration in floor during the process.
Now imagine ball as a wave of force. This wave will reflect like a ball at a certain angle but very little wave will pass through floor.
Now this may what is happening with light. When it reflects some of its energy or em wave passes through the surface . And thats why we may see a drop of light...

You are so good at explaining sophisticated subjects...like your videos so much 👍👍👍

“Isn’t that interesting?!” And I don’t even know what I’m looking at lol

Hi Jade. You alluded the continuity of evanescent waves at around 5:49. Fundamentally in nature, there are really no abrupt changes at things with boundaries--it's exactly what you are explaining when you described non-infinite potential wells. You have to have a matched boundary condition and the natural way that happens with optical materials is to have an exponential fall off. I think you can look at it as a photon having a physical extent in that is has a spatial wavefunction associated with its position. As the photon approaches the boundary in the glass, the wave function of its position crosses the boundary and extends outside the boundary. The shorter the wavelength of the photon, the more confined it's likely position is and the faster the evanescence wave (field) strength falls off on the other side of the boundary--the wave number gets larger with photon energy causing the field to fall off faster. Thanks for making videos on this stuff.

I liked the surprise goodbye at the end made me jump! I’m hanging thru every word you say so that one was an unexpected surprise, fun

I love how enthusiastic you are explaining all this stuff to us 😊

The e^(-x) function approaches but never reaches zero. Does this mean that quantum tunneling is always possible, but just increasingly improbable, for any non-infinite potential barrier?

!!!
You gave me an "ah-ha!" moment of my own!
A few months ago I was researching equations of state, specifically SAFT. It basically models the molecular interactions between particles. I came across certain potentials and what not and it all made enough sense for me to at least conclude that the potentials affect the strength of interactions. Fast forward to today and here you are explaining what a potential well is and I'm like "OH MY GOD! THATS IT! THATS THE THING!!!!"
You do amazing work. Keep it up and thank so much for that wonderful moment!

I am a 1st year engineering student and I missed the lecture on wave function.
But YOU came to my rescue and helped me in that .
VERY VERY THANK YOU .
🎈🎉🎈🎉

Some of questions. 1) does the energy of the particle in the wave function determine how long the evanescent wave will last?
2) If the energy of the particle does contribute to the duration of the evanescent wave, is there an upper limit to how long the evanescent wave can exist?
3) does the material that the evanescent wave travels thru effect the duration of the wave? for example can an electron tunnel thru 1mm of paper, but it couldn't make it thru 1mm of lead. (a millimeter is a huge distance for an electron, so assume I am smart enough to know the correct units of measurement )
4) does the mass of the particle in the wave effect the length of the evanescent wave? Would a photon evanescent longer than an electron (all other things being equal)?

Amazing vid!! Didn’t feel like a dumb ass the whole time, your kind vibe really puts me at ease and heck the content is cool. Nice one

Your passion for the subject is commendable. Thanks for making me pass this semester :)

Now this i call a good explanation ! I like that you included the equation into the video. It would be cool if you could do that with more videos.

A good way to Intuit quantum tunneling (for me anyway) is to imagine a wave (of water) breaking on rocks. Some of the water jumps the rocks and ends up on the other side. Wave mechanics is (for me) very intuitive if you visualize the waveform as a literal wave made of a fluid (the water analogy also works for GR and the warping of spacetime if you include bubbles in your visualization). Hope this helps in some way

Jade these continue to be wonderful to watch. Clearly lots of people agree with me, which is reassuring. "Evanescence" is a good theme because according to (Stephen) Stigler's Law of Eponymy , "No scientific law is named after it's original discoverer." I believe that James Maxwell, while he was a genius, no doubt, left us with almost 20 Equations and that it was Oliver Heaviside who further transposed them into the 4 equations that now fit on so many t-shirts world wide. This video furthered my understanding about how transistors work for us.
I love your stuff! Please keep it up!

I love the general background music on your videos. It's oddly relaxing.

What the?That's the best video so far on tunneling on youtube.Sorry for not subscribing and looking into your channel before.Nice job.Keep it up and never lose that smile and energy😊

At 3:30 I have a feeling there's a typo in the last of Maxwell's equations, Ampere's Law should be curl not divergence!

Best explanation I've seen so far, after 6 vids

Finally, an explanation of an effect I have to know most of my life but whose maths is too complex for my small brain to work out. Thank you.

watched alot of videos on UA-cam and this is the first one that explained in a way I could understand. Good work!

8:27 'I didn't really understand the schrodinger's equasion untill I solved it myself'
YOU DID WHAT?

Well wave cannot drop to 0 and stay there because solution to wave equation is always an exponential one and exponential solutions never stay at 0, they either exhibit exponential decay towards 0, or behave like a sine wave and wiggle around 0 if you allow complex exponents, but it still means that it has zeroes but doesn't stay 0 as y=0 is a line, which is linear and not exponential solution, and wave equation doesn't have a linear solution...

You should do an example problem for each of these videos. They are so great, but it would take it to the next level, to see actual quantum physics problems worked through that aren't just a theoretical proof type problems. Basically giving actual boundaries, Energy states, and probability values. Keep up the great work!

Extremely helpful
Please keep bringing stuff like this
It's Really easy to understand the concepts from u....
Thank u

Outer Wilds brought me here

2:10 Who is the guy surfing on the wave function on a rainy day?? Because of quantum tunneling there is a limitation to how small transistors can get btw great video as always keep up the good work

I just found this channel and I'm already subbed. I like your style :)

Thank you for the clarification about the box which holds the electron being conceptualized as an infinite potential well--this is something that I've always wondered about and never saw explained before. At Minute 1:29, it's mentioned that the Heisenberg Uncertainty Principle creates the lack of knowledge of the position of the electron prior to measurement. The Heisenberg Uncertainty Principle tells us that to the extent we know the velocity, we can't find the position. But the main reason we can't pinpoint the position is that, prior to measurement, the electron is in a superposition of all positions in the box, per the Schrodinger Equation.

"Can you learn quantum mechanics without math?"
" *B R I L L I A N T D O T O R G* "

darn, i really thought u were going to talk about the "why" of the decay instead of just the "what". oh, and i looked at that box and thought of wyoming.

This video is so good! Was looking to understand quantum tunneling in the isotope effect and this helped alot!

Hey Jade! I know you get a bajillion comments like this, but I've been meaing to to say for a while that i love your videos and that your channel is definitely one of my favorites. You do an exquisite job explaining complex subjects that I'd otherwise never understand. Thank you so much for doing what you do and keep up the good work!

Why is quantum tunneling essential to nuclear fusion in stars, spontaneous mutation in dna and scanning tunnel microscopy?

Could quantum tunnelling be explained by errors in the simulated universe's collision detection?

Really liked the video, the frustrated total internal reflection part really helped me with visualizing what is going on.

I come from Tom Scott's channel. That video on knotss was HECKING AWESOME. It blew my mind! I can't wait to watch your videos on Quantumn, I'm actually in Quantumn 2 in my college course but sure a refresher is always nice!

Earliest boi , also hi Jade this could be a little but different than your usual videos but could you do something on what do you do after graduating with a physics degree

Brain.exe is not responding

This video was just next-level for me. Brilliant, well done! :)

You're great at explaining things! Thank you for making videos! :)

Quantum jumping with J A D E 👩‍🏫👸👊👋👏👍👌

I like your explanation!
But if it's an infinitely thick-walled box, can it have an "outside" to begin with?
I think the probability of it outside being zero is because there is no outside.

Thank you so much! Your video clearly explained a concept that I had never really been able to grasp. ⭐⭐⭐⭐⭐

Excluding the random extreme close-up, I genuinely think you are really starting to nail down the presentation in this videos. This chill and stripped down approach works really well, and btw, great video! ;)

Thumbed up for shamelessly admitting that you're not good at physical experiments. Neither am I. :(

Exponential decay never reaches 0 though.

You made this really fun to learn. Thanks for keeping your audience in mind

I've just discovered your channel. Subscribed immediatley. Thanks!

Hands up if Tom brought you here?:-)

Loved It!! ♥ Also, about the question you asked, I'm not really sure, but here's my try - when a wave strikes a surface, some components ( the parts of an unpolarized wave that have a component perpendicular to the plane ) don't get reflected 100% & some of it passes through, making the evanescent waves. Like I know it's not a physical enough explanation, but it's really not imaginable in 2D I think.

I swear, your method of explaining along with your visuals make quantum mechanics so much easier to comprehend.

Lovely video. I have just started to work on Quantum Biological Electron Transfer and your video helped me to get some basics rights.

This was a really great explanation. Thank you. New sub!

Great video I learned so much!

Years ago now, in our Quantum Mechanics Lab we did the tunneling experiment by reflecting a microwave beam within salt blocks ( more commonly used as nutritional supplements for cattle). We "shined" the microwave beam into a right angled rectangular prism and the evanescent wave would jump (tunnel ) the gap to an identical salt prism almost touching (gaped) at the hypotenuse. Thanks for doing Your videos.

4:30 I think the term Evanescent wave is apt because, after a brief moment, the light ends up waking up inside the stuff it's passing through.

Thanx for sharing this knowledge. I learnt 2 new things today viz. Evanescent wave and FTIR.

Thanks! It's something I needed to know to understand QM better.

I work in optoelectronics for telecommunications. Very good video, especially the total internal reflection and exponential decay.

amazing video! I think the evanescent wave could occur just because entropy must maximize by doing so and/or when calculating the path of least action (stationary action) of the light by deriving the Lagrangian. I think it happens this way in particular because no transfer of anything in nature (energy, information, mass, etc) is perfect, so I would expect some imperfection in that angle of perfect reflection as well (maybe also be uncertainty principle and that causes the imperfection and subsequent evanescent wave?). I have no idea but very fun and cool to speculate about

5:19 You have to think about the waves as oscillations of the electric and magnetic fields. Since there is oscillation at the boundary, the fields must be affected in the immediate vicinity. The best analogy I can think of now, for some reason, is contagious dancing in a crowd. The people on the other side of the 'boundary' don't really want to dance, since the people on this side are directing all the 'energy' of their dancing only to the people on the same side, but those on the other side who are nearby can't help but sway a little.

To answer your question about frustrated internal reflection, I think if you consider the barrier of potential as consisting of many vibrating waves, there is a some chance that some of those vibrations will constructively interfere with the wave of light, pushing it just slightly passed the barrier itself, and producing the evanescent wave. In other words, throwing a tennis ball at a vibrating wall, if that wall has just the right vibration, it could facilitate the tunneling of that tennis ball just barely through its own medium. (Please feel free to correct me if this doesn’t make sense, just a hypothesis).

It's very great quantum tunneling!!! I really am eager to see some videos on highs boson..

@upandatom, you are doing a fantastic job... keep it up

If you want a physical representation of a wave, you can always use water(as an analogy). For example, if we had a bunch of water on the left of a very tall thin wall you could imagine the waves on the left "vibrating" the wall and therefore passing through it at lower amplitude. This works fairly well to show why thicker walls work better. Though it probably should be noted that this is not how reality actually works but a good intuition for it.

Thank you for making these!!

This was by a mile or ten the best science communication video on quantum tunelling I've ever seen.

Very well explained, thank you so much!

Thank you, for the time you put into teaching us these topics.

Great video. At 5:47 you request a good physical explanation why the wave cant change direction at an interface without an evanescent wave. My take of this is:
The wave has to "decide" what to do when meeting an interface. In order to make this decision it must know what kind of interface it is, so it has to probe it before it can "decide" what to do next. Probing means it must penetrate the material to some degree in order to interact with the medium.
For this it need the evanescent part.

Thank you! I never get to understand that before this video. Keep it up👍👍👍

Yaya keep talking , I love how you explain these complicated concepts so easily🤓🔥

So well explained. Thank you.

I have been working on flash storage for the past 10 years and all of your solid state drives actually use quantum tunneling to store the bits!

I literally discovered and subscribed to this channel in 10 seconds. So good

Your humbleness in this video is certainly one of the most beautiful things I've seen in a while. Can you please make a video about String Theory? It would be great. Greetings from Brazil. ❤️

Great video.
The explanation of quantum tunneling is like reducing a fraction to its lowest terms.
Wonderfully simple but yet elegant !!!
😺😺😺

Perfectly understandable explained ❤️

I wish these videos were around when I was really into this in high school. I still am but now I’m in university and this was helpful toward my learning

still cant believe how well you explained everything