Please keep continuing this. There are so many of us who yearn for such quality content

We don’t often see this unique approach to a mathematics problem. I hope this series continues.

Guess I've found a series to watch this summer

I thought this was about to be the greatest collaboration between formula 1 racing and advanced mathematics

I’ve seen lots of content on the RH, but have never seen someone explain ACTUALLY how the zeros on the critical strip related to the primes! That’s amazing!

This is very high quality content. I am a first year mathematics undergraduate and appreciate that I can understand concepts of such advanced level because of the way you dissect each and every part. Please continue these videos!

Awesome video! I'm very happy KZbin recommended this to me. I always wanted to understand how the Riemann Zeta function is related to prime numbers and you explained it so clearly and easy to understand. Keep up the great work!! I'm really looking forward for the next episodes of this series :D

I'm super excited!

From a mathematician, thank you very much for the video and the references!

The way you deliver is mesmerising. I could listen to this for hours

I am a complete layman and in fact a high school dropout. I try to catch up to maths and other subjects in my spare time, and I don't shy from esoteric or advanced topics such as the Reimann Hypothesis because of the simple fact that all the other people who discovered these things were also humans. Your way of explaining is one of the most easy to follow. A nice mirror to the other awesome KZbinrs like 3Blue1Brown. Whereas they try to beautifully simplify things from alternative points of view, you approach the problem head on with clarity and patience. Thanks!

So wonderful and well executed, I can’t wait for the rest.

You explained it so simply and clearly. I like how you highlight the clues to tie many concepts together.

Premium epic math content for free is the greatest achievement of the internet

The examples at 8:49 made it very clear to me exactly the algebraic numbers one finds in P, such a great video series. Rewatching now that I know more than I did before, and will continue rewatching until I understand everything in this video. I want to prove myself right. Thank you for your content, sir.

Good lord I'm excited for this series lol

I have NEVER been so enthralled by a topic in mathematics. Eagerly awaiting the next installment!

Best math video on KZbin this year. I've always marvelled at how productive Archimedes was with such a limited notion of number that I decided maybe my notion of number was the problem. We treat transcendentals like integers all day long and never bat an eyelid. Have you ever done a calculation with pi? No you haven't.

I'm a math's student. and you are the teacher like god. I salute you for introducing this pure Knowlege us. I wish, someday I will go deep down this L-function world and make out something. thank you .

Strong start! I hope future videos, once we've gotten through the big-picture overview, dive deeper into the details and rigor of the problem. In the meantime, I appreciate the links to the papers youve cited!

Absolutely beautiful video.

going into my 3rd year of mechanical engineering, I have almost zero idea whats going on but still super interesting to watch

Love it. Commenting for reach.

I'm a mathematics graduate student right now working in non-commutative geometry, operator theory, and field theories. I'm not particularly interested in working on the Riemann hypothesis myself, but (while not necessarily frequent) I do recurringly hear and read about how the the stuff I work with has various sorts of connections with the Riemann hypothesis, and I do find that rather fascinating I hope this series continues! Though I don't plan on ever working on the Riemann hypothesis myself, I'm excited at the prospect of hearing an extended pressntation which elabourates on some of those connections I've heard about!

Physicist chipping in here. You are putting the bar high up there, love it! I look forward to all the next episodes. Hope you will extensively cover random matrix theory as well.

Accessible yet not too dumbed-down, simply AMAZING!

Amazing content. Very clear and brilliantly explained. Thank you!

Great work! Looking forward to seeing more!

You showed iconoclastically that 1 is prime. congratulations !

Nice work! This was the first explanation I've seen of how Riemann actually relates to the primes, via the Riemann spectrum and the cos(K ln(x)) sums... I love when I see new material like this when I know it's been out there all this time. I'll be waiting for your next episodes!

Looking forward to your next video!!!

I'm impressed by the effort to look at numbers and RH at a different perspective, given RH has been around for more than 160 years and yet to be proven!

Great delivery. Greatness being served here. “If I have seen further, it is by standing on the shoulders of giants.”

I just began watching this series and am already enthralled! Thank you so much.

Excited to see future episodes!

Can't tell you how excited I am for the series. Please do continue !

Can’t wait to see this channel grow🎉

Here's a comment on Random Matrices. The coincidences between the asymptotic statistics of eigenvalues of random matrices and zeros of the zeta function are striking. But they are only probabilistic in nature, referring to averages over large sets of random matrices, not to any particular linear operator. At first sight, this only implies that these may somehow belong to the same "universality class", when properly scaled. The use of a spectral approach to proving the RH would have required showing the existence of a specific linear operator, whose discrete spectrum coincides with the zeta function zeros, and which is invariant under an involution whose fixed points are the critical line. Nothing like this has ever been done (for the genuine zeta function) - although analogs for prime number fields have been used to prove the RH in those cases. So the resemblance to the statistics of the eigenvalues of large random matrices is perhaps helpful in suggesting such asymptotic properties for the zeta function zeros, but it does not mean that a spectral approach provides the key to proving the RH. However, it is an appealing idea that, especially for physicists familiar with scattering theory, is very natural, and perhaps should be further pursued. It is just that the class of linear operators used in proving the RH over mod p finite fields, which were discrete analogs of the Laplacian, need not be the same as the one required to prove it for the usual zeta function.

It's beyond amazing to see the mathematics of reality. It's incredible to see the very building blocks of our existence, far beyond the quantum level - in number form. Wow.

An excellent introduction and overview of the topic. Thank-you so much for taking the time to make such an accessible, well-paced, clear video on the search for proofs of the RH. My hope is that this stimulates young & old mathematicians to embark on this journey of discovery.

i dont know anything about math but the sum of negative cosines feels almost like a transcendental number like e, getting closer and closer with each continuation of a function, never reaching its full value. its like one step forward from a number. this comment is just for the perspective of what people with only basic math knowledge might think of this video.

I love the way you've framed this, a mystery and an adventure!

Thank you for starting this series. I sincerely hope it continues.

Looking forward to the rest of the serie !

I very much hope this continues, great work!

This series looks like it's gonna absolutely amazing, please please please give us more!! 🙏

Very interesting, please continue the series. 😊 A short personal anecdote, because I thought you were going here when connecting the primes to the Riemann zeta function: Some 38 years ago, with only freshman physics education, and never having heard of Basel problem or Riemann ζ, I was fiddling about with factorisations and found that the product Π 1/(1-p^(-k)) over all primes had to be equal to the sum Σ 1/n^k over all integers (for some fixed k>1). My dad saw my notes and wanted to show it to a mathematician friend of his. I protested a bit, because It was only a few scribbles showing the idea to myself, but he persisted. A few weeks later, I got it back full of red stripes, because my 'proof' was wrong. My dad then lost faith and thought that all of my scribbles were nonsense. Later I found out that Euler had found the same result. Probably the mathematician had thought that I wanted to show a proof for Euler's result, or even trying something with ζ(k), whereas I, naive as I was, just thought to have found an interesting new connection between primes and powers of natural numbers, and had not focused on (and probably could not provide) a watertight proof.

A lot of interesting points in one video. Great job! 👍 I love to see more videos on this topic. I hope this series continues!

Sublime video, I think we are all looking forward to the next chapter. Thank you!

Fascinating video with great explanations. I look forward to continuing our journey through this subject.

Sidebar: I'm too bogged down doing yard work to think about any of this stuff using a well rationed bottom up incremental procedure, but, when I see a list I always want to sort it vertically within 25 orders of complexity to see if I can convince myself of soundness and its' derivatives, and laterally with circular relationality to convince myself there is tension and proximity to a singularity. After that, all proofs should be local to the spread, unless captured by new top down notation or circumstance. It's like lying about everything, untill one finds the missing link that connects everything to the core spectral tree. To maintain interest, I might try to plot the args between the non trivial and discovered half zeros, just to get that notion out of the way. After that, I might try to see if prime spirals pass through zeros. Beyond that, I might try a complex basis, for a complex function, instead of just relying on the real natural. After 6 months, and all that snow shovelling and lawn mowing, if I hadn't got anywhere, I'd give it a rest, and move to plan B? In plan B, I might generalize complex basis into radial or steridian arms, and choose the one that stayed true the longest, or offered the possibility of predictively jumping basis, to a new complex basis? Plan C, now 2 years down the road, and retail computing aside, pocketing positional bread crumbs just might produce a computational thread, or confinement proof, which brackets expectation, and a re-sort of prior lists? Plan D, sluffing off real mathematicians who incrementally produce the notation for real thoughts, rather then guys that just count to the limits of thought and contradiction. Plan E, transforming zeta into a torus and coloring the holes, and then trying aspect projections to line them up into some spirals? Oh well, just a thought that paper hanging isn't going to work, but optical discovery might. Plan F, predicting a change of basis to find the next conformity to consistency, and maybe discovering a hidden singularity that requires discovery of its' charme, before categoricalicity can be claimed. Plan G, compactness still illusive, but completeness expected any day now, after 6 years, ...dwelling now on shadow biological spectrums that don't actually exist other then in the mind, but which can be calculated in digital form, and thinking these are the numbers that are actually also invisible functions, and singularities that have always been taken for granted? Plan H, staying away from psychiatrists who insist everything is real, otherwise you're living in a delusion, and soon to be placed under administration, just so the government can claim patent discoveries they may never have any possible valid natural title to, other then from escheats by divorce, estate, and probate lawyers who are also impunity criminals for publically elected celebrities? Plan I, retracing the path of "i" before it became a singularity operator? It's year 7 now, ...and the city is entertaining complaints that a hermit hadn't been mowing his lawn, and the yard is an eyesore, and there should be a law against people like that. Plan J, discovering that sequenced 2 way spirals, vertical and horizontal, are way better at prediction, just perfectly matched to new optical retail computers that are a billion times faster then they were 10 years ago, and can 3D print lenses for formating 3D schartz christoffel constructors that prove a whole new branch of discovery unknown, but predicted say 8 years ago? Plan K, the realization that the general construction company had a singing frog that only performed on Sundays, every other prime week during some, but not all moon phases where saturn and jupiter were in each other's conflict. Oh well, the city is now threatening to claim the property for lack of tax payments, but completeness is still an unknown incompleteness witch, and a common half bitch, and those orders of complexity to complete, now exceed the mental capacity of every researcher to date, including the latest persistent believer. Plan L, figures that incompleteness on this proof might exceed the natural spectrum, and that augmented cosmic metals are required from yet to arrive space junk to justify and prove realization of the previously invisible. Plan M, praying to the void and expecting a delivery of new resources from a worm hole. Plan N, joining a registered arctic coven that licks frogs for inspiration. Plan O, kneeling next to a tall tree and passing in the zen forest. Well, that's it. Good luck.

Great presentation

Absolutely wonderful start. I'm looking forward to the continuation

Absolute respect for using Ravel's g minor concerto as the background music

Absolutely loved this introductory video! You're a great storyteller and have me really excited for the future episodes! As a math student, I love seeing stuff like this

I will look forward to the continuation. I liked the measured pace with which the main points were introduced. And I also appreciated the "focussing on the key points" in the Manin and Conrey papers. But, of course, as you said, this was just a guided tour, and not yet an explanation. If you could render Manin's paper more accessible, that would be of great value. Conrey's result doesn't go any way towards a proof of the RH, of course, so that may be interesting, but only of secondary interest. The relation to Random Matrices is also nice, but goes no way towards a proof of the RH. I will follow with a comment on that.

I am very thankful for this series and so glad I found it!

Just stumbled across this series and I am excited to watch it all.

This video is a thing of beauty. The presenter's approach was just right and I even loved his long pauses. The tablet was a perfect choice, while the hand drawn notes humanised it. I was drawn in to the subject matter and felt engaged from the outset, as if I was part of the adventure. The only thing I didn't like was that this was the only video on the channel. Please can we have more like this.

I can see some sort of deep connection between quantum mechanics and number theory from this presentation. Never realized this before.

Instant subscription

Love to see more such videos. Fantastic introduction and inputs.

Please don't stop. Can't wait for S2.

I haven‘t been dealing with L-Functions since my days at university… :-) Interesting lecture series - keep up your great work!

Thanks

This is truly exciting series

I am glad that youtube recommended this video for me. Very excited to watch it and eagerly waiting for the next ones.

Now this is some high-end KZbin content. I am here for it!

Excellent review of the RH, the best I've seen. I can't wait for the next episode.

This is insane!

The algorithm suggested this to me and this is exactly the kind of content I love. Subscribed, and hope to see more videos like this!

I just subscribed to see how this plays out. The suspense is killing me.

From the beginning to end everything was perfect. Waiting for the next part. Thank you!

I wait with baited breath. Truly an excellent video

Can't wait to hear more about it.

this is so well made. looking forward to see the up-coming episodes ouob

Wow this got me hooked right from the start. I am looking forward to the next episodes!

What an amazing introducton. Superb.

Thanks for all your hard work. Great introduction. Looking forward to next episodes.

I'm watching for the second time and love what you are doing. Thanks!

How interesting. I was just thinking about the idea of numbers as functions working on a project where I’m seeing strange phenomena of numbers that I’m seeking to find an explanation for. Nice to come across your video and that wasn’t even my search query either.

Amazing... అద్భుతం...

You managed to catch me, very nice approach! please continue

That's so exciting and well presented. Can't wait for the next episode. It might feel a bit like the lecture of Wiles, where he casually proved Fermats last theorem without explicitly telling in the Titel... Greatfully, Alex

One of the best introductions I've seen to prime numbers and RH. Thank you! As a lay person I'd like to ask something. To me, there clearly is some sort of geometry to numbers, they are a geometry. One we seem able to just see, as far as we look at numbers and what they do. All it takes is looking. How do numbers stand and behave relative to eachother. Now, one thing is to look at that and describe it, while another is being able to predict things. Why should we be able to predict everything, meaning anything in particular, without computing? We may find a proof of something, some day, or not, but does it imply anything at all about certainty, or rather lack of it, whether we haven't managed yet or it is impossible to prove that? My point is: we might sometimes actually see clearly that which isn't proven or even provable. For instance, the twin primes conjecture. To me it is by definition a conjecture, but at the same time, it seems obviously true, "visually" obvious, to be true, we KNOW it to be true. We can look and see how there will always be twin primes. It is something purely mechanical. We cannot compute all numbers in practice, but we can see how, computing them, necessarily leads to infinite twin primes. It simply is part of their "geometry". My question is: this which I am saying, does it make sense to any mathematician here? Would any of you agree that you can see it (how this conjecture is true) and be just as certain, without a proof? Thank you!

This channel is probably the best thing that happened to Mathematics after 3Blue1Brown

Mathematical reality TV - awesome concept!!!!!

This is extremely good quality content. Will you discuss the work of Deninger at some point? Perhaps a discussion of Connes’ noncommutative geometry approach might be worth talking about too!

I haven’t started this video yet and somehow already know I am going to love it!

I found this channel in his begining and I am glad

This is exciting

Such high quality! Your channel will definitely succeed if you continue. Keep it up!

Will be waiting for part 2 and so forth. Cheers.

Wonderful and inspiring video. What a time to be a student of mathematics.

I like your way of presentation.

Looking forward to the next episode!

Wow! I didnt get everything at all but i loved the way you went through the hipothesis and the structure of the video. Thank you!

thank you for your prescience great stuff staff and viewer

1) Zeta function relates to Primes by the Euler Product. Therefore Zeta spectrum has information of Primes. 2) Finite sum of cosine waves (in Fourier Transform) is a way to use sum of continuous functions to approximate "almost" discrete function, Delta or narrow spikes at Primes and Prime powers.

The spectrum take is beautiful