From First Principles - China’s AI Breakthrough, Time Crystals, Hidden Viruses, & Brightest Cosmic Signal (EP. 9)
Episode Date: September 23, 2025Lester Nare and Krishna Choudhary return for Episode 9 of From First Principles, breaking down the latest breakthroughs across AI, physics, biology, and astronomy. From China’s stunning AI leap with... DeepSeek to time crystals you can actually see, hidden viruses in our DNA, and the brightest fast radio burst ever detected—this episode spans the cutting edge of science and its global implications.Summary• China’s DeepSeek AI model: geopolitics, open science, and the future of AI competition• Time crystals at room temperature: from theoretical physics to practical cryptography• Hidden viruses in our DNA: new structures decoded with potential for cancer & autoimmune therapies• Brightest fast radio burst: unraveling cosmic mysteries with new telescopes and James WebbShow Notes• Nature: China’s DeepSeek AI paper (1)• Nature: China’s DeepSeek AI paper (2)• Nature: Time crystals with liquid crystals• Science Advances: Viral protein structure discovery• Astrophysical Journal Letters: Brightest FRB
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Hello, Internet.
This is your captain speaking.
Lester Nare, joined as always by my co-host and our resident PhD Krishna Chowdery.
This is from First Principles.
We have a great episode for you this week.
We're going to cover four stories in AI, space, and immunology, starting with,
a new story out of China's Deepseek, which says its AI model costs just $294,000 to train.
This is really important, and we're going to go a deep dive into Y.
Followed up by our second story, sounds like we may have discovered the ocarina of time.
We may need to get Zelda involved, as scientists just made the first time crystal that you can see.
I'm really interested in talking about that one.
The third story is about hidden viruses in our DNA.
That could be medicine's next big breakthrough.
And we're going to end with space with the brightest fast radio burst ever detected
and how it could help us solve an enduring cosmic mystery.
This is from first principles.
My friend.
How's it going?
Episode 9. 10K followers on Instagram.
We still haven't been shut down by the FCC yet.
Yeah, yeah, yeah.
It's coming, though.
It's coming.
We're talking too much science.
It's coming.
It's coming. They're going to defund us and then ban us.
But before they do, we're going to talk about some great stories.
The first one, we always end up touching on AI.
There's a lot of research going on in AI in a variety of ways.
And our first story was a story in Reuters that also had two nature papers that were related to it.
The headline on this is China's Deepseek says its AI model has hit a cost of just $294,000.
to train.
The sort of byline is in a paper that is likely to reignite the debate over Beijing's
place in the race to develop AI.
Yeah.
This sort of cost, which is significantly lower than the figures that we see in the U.S.
And I know we've talked about Deep Seek and all of this quite a bit.
Yeah.
It's a crazy model.
And the fact that the team put out a peer review paper, you know, no one else has done that
in the field of AI, like gone to nature and put out, okay, this is how we trained, this is how we did it.
You know, it is very interesting.
They're actually, it's kind of crazy that China is setting the precedent for open science in the field of AI, right?
It is very interesting.
And not only one, but two papers in nature main brand.
Not a nature sub, you know, sub category.
This isn't ICCLEE.
This isn't even like, you know, NERIPS.
This is nature.
And, you know, what I thought would be helpful, we're going to do sort of two aspects on this story.
Yeah.
Folks might have seen the Deep Seek news, you know, earlier in the year when there was sort of a big outcry about it.
Yeah, they released in January, I think.
Yes.
And then all of our stocks failed.
Yes, it was a big deal.
Yeah.
But January wasn't the start of this great power war over AI.
Right.
And I thought it would be good to just go for a couple of beats on the sort of geopolitical context.
that this research paper kind of came out in.
Yeah, yeah.
And to sort of set the stage, right,
there's an AI great power competition
between the U.S. and China.
AI, as we know, it has existed for quite some time,
you know, before all this generative AI stuff.
But in the sort of recent context,
we're going to start in 2017
where China launched its next generation AI plan,
which said it was going to lead the world in AI by 2030.
They're famous for their five-year plans.
Right.
And the idea is U.S. has been the global hegemon forever.
China's looking at a way in which it can sort of destabilize that control.
And Xi Jinping, leader of the Chinese Communist Party, said that advanced tech is the sharp weapon of modern states.
Yeah, that's true.
And as we've discussed on this podcast previously, there is a very strong relationship between them.
Military intelligence and national security apparatus within the...
nation states and frontier technologies.
AI just being one of those.
And then in 2021, what was interesting is the U.S. National Security Commission on AI,
which was chaired by the former Google CEO, Eric Schmidt, warned that American dominance
in AI was not guaranteed.
So we already have this setup of that friction.
Wow.
Now, if we go into the Biden era policies, because the U.S. government, as we know,
as it relates to technology innovation, is usually reactive.
as opposed to proactive.
Yes.
We look at the internet as an example.
They allowed innovation to happen
and then they put in a regulatory infrastructure
after the fact.
With AI, because of the popular conversation
from the likes of folks like the richest man in the world,
depending on the day, Elon Musk,
really ringing the alarm on, you know, AI safety.
Yeah.
Which has created this accelerationist,
decelerationist dichotomy within Silicon Valley.
The Biden era was the first administration
to take policy in earnest in terms of,
AI specifically. Okay. And this started in August 2022 when Biden signed the Chips and Science Act,
which many people probably heard the Chips Act. Yeah, the Chips Act. $250 billion,
bipartisan bill aimed at boosting U.S. Semiconductor manufacturing and innovation. This dovetails
with the re-onshoring of manufacturing conversation post-COVID. There was 52.7 billion in
supplemental appropriations that was specific to semiconductor-related programs. Okay. For 2023 through
2027. The idea being that it was also going to create guardrails preventing recipients like
Intel and TSM from expanding their advanced fabs in China. So we can see the theory of the case
here was can we create a choke point at the hardware level because these chips were viewed
at the time as being the key aspect of the stack that was going to be the driver of progress
Right. And innovation. And TSM is in Taiwan, which is like now iffy, if it's, if China's going to do something, right? Correct.
China's been doing a huge military buildup and training around this idea of we're going to take Taiwan.
Yeah, yeah. That's basically their thesis. We're going to take Taiwan and you don't want to be here when that happens. Yeah. To us, the US. Yeah. Yeah. And so there's scary. There are a lot of layers to this. The Taiwan points are really important one. Now, 2022, we're still in 22 August, chipsacked drops.
And then October 7th, 2022, the October 7th controls were established, which are export controls.
Now, they named it this prior to the unfortunate October 7th of 2023, which is the Israel-Gaza conflict.
Right.
But at the time, this was a restriction on exports of specific Nvidia and AMD chips, the H-100s, A-100s, and the AMD-M-D-250s, which basically meant.
This was the whole, we have a small yard, high fence.
Yeah.
Making it really, really difficult to get these sort of frontier chips.
Yeah, and the thesis was that like these chips are the future.
Yes.
And without these chips, you can't do shit.
Exactly.
That was the theory of the case at the time.
Yeah.
As a small side note, it's interesting that a month, almost just over a month later,
in November 22, 2022, Chachiby T launched.
Ah, okay.
So all this conversation was happening prior even to the,
the meteoric rise of the first real, you know, production level,
uh, LLM generative AI accessible to millions of people and the growth curve, as we all know.
I mean, that chat GPT was the moment where now everyone was like, oh, AI is here.
Yes.
It's not just this thing people are saying.
Yeah.
That's not theoretical.
I, I can literally chat with it.
Yes.
And it's like giving me amazing answers.
Yes.
Yeah.
Yes.
Yeah.
So now we're moving into.
2023.
Right.
So throughout
2023,
now the Biden
administration
is not only
trying to
create the choke
points domestically,
but now we're
going out to our
allies all across
the world to
sort of expand
that tightening.
So this included
in the Netherlands
with ASML.
Right.
In Japan, with
Nikon and Tokyo
Electron,
blocking them
from providing
China access
to their lithography
tools,
which are used
to actually
build and generate
these
more advanced chips.
Yeah.
This was followed up by in August of 23,
Executive Order 14105,
which now also restricted investment
from U.S. investors
into any China AI or quantum firm.
Okay, so they're just like effectively slowly,
like choking all pathways.
Right.
For hardware innovation.
Yeah, for hardware innovation.
For hardware innovation.
Okay.
Right.
So while this was all,
happening in 23, interestingly enough, there was the very sort of public falling out of the
founder or CEO at OpenAI, Sam Altman. So many folks may remember there was that huge board battle.
I forgot about, yeah, dude. He was ousted at CEO. He was ousted. Yes. And this was around Open AI was a
nonprofit. They were doing a lot of for-profit moves. They wanted to kind of rejigger their structure.
and it kind of signified the realization
across the Silicon Valley consensus
that this thing was going to be bigger,
more powerful, more impactful, more money generating
than even they had seen, that had predicted.
It was happening quicker than they expected.
So there was that power struggle.
Right.
Ultimately, the king returned to the castle.
Yeah.
And Sam re-got his position as CEO.
But all this we've talked about so far
has been the U.S. side.
Yeah.
So in 23, China's response, like, what has China been doing as the U.S.
That's right.
So, yeah, we've been battling internally, so to speak.
And to sort of create this regulatory regime around access to chips.
Right.
So what's China been doing?
So China had firms like Huawei introduced their own, you know, what they call frontier chips.
Yeah.
With the Ascend AI chip, as well as shocking the global community when SMICs,
released their 7 nanometer process for for smartphone chips which again the idea was
TSM has really had a monopoly on the 7 5 and I believe three now nanometer chip
sizes their latest is three but like sub 10 was them what right and no one else
could really do it and that was like a really big bottleneck yeah both for and
there's both operational reasons and proprietary intellectual property reasons
why that's difficult yeah they also then had
had their other big conglomerate technology companies,
Baidu, Alibaba, begin to put out their own chat GPT type LLM.
So we had Quinn, we had Ernie Bot.
But nobody really...
No one really thought anything.
Nobody cared, right?
No one cared.
They were all trained on the cut down Nvidia H-800 GPUs,
which were still allowed to be sold to China,
but they were massively sort of handicapped.
Yeah.
Interestingly, now we're sort of getting into 2024,
which is more of the same, but we talked about the intersection of the national security state,
the intelligence community, military intelligence, and frontier technologies.
Yeah.
And Mark Andreessen made this interesting note in a podcast where he basically was trying to call out
the folks who are called decels or the folks who are really heavy on AI safety.
Deceleration.
Yeah, the decelerationists who are saying, let's slow down, let's slow a roll.
Got it.
Elon is a famous one.
Elon is arguably the most famous decelerationist.
And Mark Andreessen's point was,
if you believe that this threat is as extantial as nuclear weapons,
you're still allowing these open AI employees to go to an unprotected,
unsecured building in the same way that,
not in the same way that nuclear facilities are protected from an operational security perspective.
So he's like, if you believe this to be true,
the entire operating infrastructure of these companies needs to change.
Yeah.
That's fair, actually.
I never thought about that, but yeah.
It's a fair argument, right?
Yeah.
And in 2024, on June 13th, after all this board kerfuffle in 23, the former head of the National Security Agency and commander of U.S. Cyber Command, Paul Nacassone, was added to the Open AI Board, which was the first salvo in what I like to call the nationalization of the frontier models in the United States.
Got it.
Right now the National Security State has a seat at the table.
Shortly after, OpenAI announced several projects with the Pentagon, the OD around using it.
So this is all background leading up to the Sputnik moment for China.
That was a big one.
Which is in January of this year, 2025, when the Chinese startup Deepseek released their R1 model,
which was claiming at the time a Chatschip-T-4-level reasoning.
So this is like our best, most front-to.
This is pre-chat GPT-5, which we now have today in September,
fully trained on Nvidia H-800s.
Yes.
The not-good chips.
The not-good chips, yeah.
Using a mixture of experts' techniques for the training
alongside with reinforcement learning at what we now understand to be a sub-300,000
training costs.
Now, it's important to note the amount of money that Anthropic,
open AI
meta has raised
to train, GROC, to
train their foundation models
is in the order of tens of millions,
hundreds of millions of dollars.
So these are, this is in orders of magnitude
difference.
And so what we
ended up creating by doing this
choke point on the hardware side
was, you know,
necessity is the father of invention
or whatever, right? Yeah. China then said,
okay, let's innovate on
on the training model and infrastructure
to try to get the same efficacy without.
On the algorithms and the software.
On the software, not on the hardware.
So this created a huge surprise
from a lot of US observers because the consensus was,
if we choke off the hardware, they got nothing.
And this totally blew that out of the water.
So at first there was fascination,
which was immediately followed by the national security
narrative taking over.
An interesting point about what China did with
deep seek was it was also, if we exclude Lama, meta, Meta's Lama, which models, which are
open source, open weights. Yeah. But arguably weren't as competitive as R1. China was the first
frontier scale open weight model. Yeah, yeah. They just published their weights. Right.
Which the point here is then you can take it and make it into whatever you want to. So the app for
Deepseek became the number one most downloaded app globally. Oh, I don't know that.
It was then banned in India, Italy, Australia, Taiwan because the national security narrative came in and it was like, this is a propaganda tool.
It's a data siphoning tool.
Yeah. Don't trust Deepseek.
But it strategically left out the point about the fact that you could download the model.
Yeah.
Run it locally and change the weights however you wanted to.
So with Deepseek, if you tried to look up Tiananmen Square, you weren't going to get an answer.
Really?
Right.
So they were, you know.
Classic.
Doing a little bit on the information control, but it's open weights.
Yeah.
So if you want the Tiananmen Square answer, you can do it on your own.
Oh, interesting.
I see.
Yeah.
The narrative really tried to avoid talking about that point.
At the same time, people started calling open AI closed AI.
Yeah.
Because they had never had an open source model.
They never had a research paper, peer review paper.
Right, yeah.
Around their process.
So now this brings us to where we are today.
with these two new papers in nature,
which go a little bit deeper into how Deep Seek went through their process.
And we'll sort of talk about this.
But I think that background is important context to understand,
like, why does Deep Seek matter?
Yeah.
Why is it uniquely different than ChatGBT, BT, then Claude,
than, you know, Gemini, all these other models?
And why is it important that they actually have a peer review paper?
We always taught a lot of the U.S. conversation around science research is, oh, China's papers, they fake the data.
Yeah.
They're not really good.
They're not where we are.
And I think this has been a unfortunate viewpoint in the U.S. about China generally, not only with cars saying they just steal our stuff.
Also with this, that is a little bit outdated.
It is, definitely.
We're seeing with cars, the best EV cars in the world are made by China.
It's not arguable.
They make them cheaper, faster, better, stronger.
Yeah.
Which we've now put tariffs on in order to say, oh, don't look here.
There's no problem.
Ford is still the best.
And AI is taking a similar, in terms of our posture, a similar political stance that China doesn't really know what they're doing.
This is not really a big deal.
Blah, blah, blah.
I think we need to be careful about ascribing a narrative that may have been true 15, 20 years ago.
Yeah.
That's certainly not true now.
That's certainly not.
We've covered Chinese research.
We've covered the hexagonal diamonds that were first created by China.
Everyone's been going after them.
Yes.
But two labs in China were going after them and actually one of them succeeded.
Yes.
Like, and it's the proof is in the pudding.
They made it.
They have all the tests.
Right.
And there's peer review paper.
Again, you can.
And it's out in nature.
It's out in nature.
Right.
And we always talk about, well, this and that.
So now that we've given that context, let's talk about these two new papers.
Yeah.
These papers are pretty incredible in the fact that they're the first peer-reviewed paper from a sort of premier AI large language model, right?
You have like obviously Chachi BT, Gemini, GROC, all of these large language models, but they haven't actually published anything that shows sort of, okay, that, you know, I'm sure that the team at Deepseek has kept some secrets to themselves, but the fact that they've actually got.
out and publish this peer review paper is, I think, quite a watershed moment for the AI community,
right? Because they're trailblazing this idea that maybe AI is a part of open science,
and maybe it should be out in the open, just like normal science, right? Where it's like you,
as a scientist, you find something cool or you make something cool, you put it out in a peer-reviewed
paper, right? And you get let experts actually talk back to you and then like see how,
things actually work, right? You want to get into the nitty gritty of it. In the technical details,
this paper is quite interesting because it tells us some of the tricks that they used in actually
making it possible to train something like Deepseek on perhaps only H-800s. Again, maybe not, right?
There's always a possibility that they're not totally forthcoming. Right. But they've sort
of laid bare some of their strategies. And I think that's
quite interesting. I want to actually just do make two small context notes that I think are
interesting here. One is one is that the the founder of Deepseek are his his story is that
the reason they ended up creating R1 was actually he was doing the trading like financial
trade like finance trading. Right it was related to a hedge fund as a hedge fund plan they were like
we want a more powerful model to utilize for so it wasn't even
even their core, it was an outgrowth of another, like, need.
And then I want to talk about this open sourcing concept of like why China did,
like, why are they doing this open source, open weights move?
There was an interesting, there's a podcast, the BG2 podcast with two U.S.
investors, Brad Gershner and Bill Gurley.
And they've been talking about this a lot.
If you look at China's strategy generally as it relates to, if you're in a world where
the US already has dominance in a lot of these technologies that are closed source.
From a how do we remain competitive angle, this is actually what Facebook did by trying to have
Lama be open is the best thing you can do to battle closed source is to create an open source
ecosystem.
Right.
That now becomes competitive with that closed source because you're going to then now get
input from a wider array of experts that invest in your version of the future.
And so for China, there was an incentive geopolitically.
to go open source being a second mover as the means by which to combat the closed source dominance of the U.S.
So this deep seek model is not an isolated incident of China using open source as a way to backstab U.S.'s closed source dominance.
Yeah, there's like a, there's a strategy behind this.
That is a larger part of how China is trying to spread its influence across these areas in which,
the current West's control and buy-in is waning.
Yeah.
I mean, I think they figure that like the world is a really big place.
Okay.
And these developing economies are exactly that developing, right?
They're getting bigger.
People are getting more affluent.
Technologies there are going to start getting better and better.
And they're going to require AI to keep up with the rest of the world, right?
And maybe they don't want to pay whatever royalties, right, to these closed systems.
I think, yeah, I think, I think, I think it's really cool.
And I think the idea that Deepsea came out, right, with their model in January,
I think it was also a watershed moment for the rest of the AI community in terms of
finding out the efficacy of something like a pure reinforcement learning approach, okay,
rather than some of the techniques that chat GPT and these other firms had used,
which was a supervised fine-tuning or this sort of human feedback reinforcement learning,
which always requires a human in the loop.
What these guys did was kind of a pure reinforcement learning approach,
and that's something that they've laid out in this paper in nature.
The idea is that sort of traditional LLM reasoning models,
what they do is they require human input in order to steer them towards the correct answer, right?
In order to be like, okay, this is not quite what I wanted.
This is what I wanted.
There were a bunch of Kenyans that were hired by OpenAI to basically do this.
And I don't know how many, but like that was a whole thing back in the day.
And, you know, that's fine for that that's fine, but it's quite expensive in terms of like getting human annotated.
chain of thought data and so on and so forth.
But on the other hand, there's actually a disadvantage to using humans
because then you are limited to human reasoning.
There could be other ways to reason about a problem
that wouldn't quite occur to a human being
that perhaps if we gave the entire control to the machine itself,
the machine could figure out on its own, right?
So there's an inherent disadvantage that I think
these guys at DeepSeek actually
latched onto, right?
And they figured that what we could do
is we could use a pure
reinforcement learning strategy
where there's a reward signal.
So the way the reinforcement learning works
is you've got your model, right?
And then it tries to find an answer.
This works for well-defined tasks
where there's a right and wrong answer
and there's a really nice way
to compare your answer
to the right answer
and figure out what a reward should be.
A reward being if my,
answer is closely aligned to the right answer, then I'm on the right track, and the strategy
that I've been using is sort of on the right track. And otherwise, maybe I need to try a different
strategy. It's actually very close to how neural systems work, right? We've studied reinforcement learning
like at the biological level when it comes to like, you know, a rat trying to find cheese
in a maze, right? We've literally gone into the brain and found that these, how,
at the nitty-gritty level, at the cellular level, how this stuff works.
And now we're kind of translating that into the AI neural network space, the artificial neural network space.
So if we use pure reinforcement learning, what that does is it bypasses human labeled reasoning steps.
And then we can actually explore just computationally the entire paradigm of how to solve the problem, which is, I think, very cool.
So that's one of the things that's revealed by this paper, the fact that they used pure reinforcement learning.
It was this autonomous exploration and a development of problem solving strategies.
And what you could see, and what they report in the paper, is you could see the network sort of use that RL technique, reinforcement learning, to get better at finding the right answer.
So what they noticed is, for example, the length of the answers would get progressive.
longer because the neural network wanted to get better and better at finding that right answer
in this large language model type of thing. They also had this thing called the aha moment,
which is when I was like, oh, this is like working way better than we thought, which is when,
you know, in the chain of thought, you can actually output the thought that this thing is doing,
right? And the model would start using the word weight.
that was never explicitly put in to the training regime.
Okay?
But what the model would start doing is as it was thinking,
if it was trying to get to an answer
and it was like sensing that it was rushing things
and just trying to get it done quickly,
it would use this thing, wait.
And then it would backtrack and try to figure out
if there's a better way to rethink what it had just thought
and then keep going.
That's like some meta-level,
like weird
weird stuff dude
like that it's just using this word wait
in the context that the word weight means
wait and let's try to figure out
what we just said in a
in a nice way you know
I think I think that's that's kind of crazy
to backtrack and then
so it developed these
autonomous sophisticated
reasoning patterns to try to
solve the problem
and it's no longer limited by
the human guided
approach. Right. Right. Right. Which also has bias issues related to human reinforcement learning.
Yeah. Now, if you have a bunch of Kenyans doing it, yeah, there's cultural differences.
Exactly. There's educational differences. And so this is where people sort of have concerns about
the Silicon Valley elite being the ones controlling the parameters and mind space that these
models sort of have. So, but this is like a very pure.
peer play version that kind of abstracts away the need for, at least in some cases,
for the human input to be such a big driver in how it determines answers.
That's right.
Yeah.
So that was the reinforcement learning part, right?
Which is like, okay, that's a training strategy.
They also had this philosophy sort of efficiency over everything, right?
Because of what you talked about where, you know, the powers that be, let's say,
have crippled their access to hardware.
So what can we do?
We can innovate with algorithms and we can innovate with strategy.
So there's a two-pronged approach that they at least revealed in this nature paper.
The first one is this idea of mixture of experts, right?
This architecture where what you can do is have a giant model.
The deep sick model itself is 671 billion total parameters,
which is on par with some of the big ChachyPTs and things like that.
I think ChachyP5 has like on the order of,
trillion or more but some of the earlier models have hundreds of billions so it's in the same
regime but when it comes to actually inference the number of active parameters used is only 37 billion
okay which is 20 times less than the total size of this network because what they're doing is
they've got they've got this sort of network on top yes that comes in in the very beginning and it's
kind of a router okay what it does is you've got you've got the 600 billion parameter
network, but if you ask it a certain question, there's only a certain subset of that network
that would be very good at answering that question. And that becomes that 37 billion part.
So they've implemented this router mechanism that takes in the prompt of whatever you put in,
and then it sort of routes that prompt to a subset of the network. And now inference becomes
faster, it becomes less expensive in terms of maybe you don't need an H100 GPU, right?
Maybe you can do with that H-800 or, you know, that previous model.
And you can actually like get a quick answer and it'll be just as good.
Right.
Right.
Right.
So that's one of the strategies that they used.
The other strategy that they used was during training, they had this idea of using a reward system, right?
In reinforcement learning, you have to have a way of sort of quantifying how much the reward is,
and then steering the network towards getting more of that kind of reward.
Right.
So the way that traditional LLMs have been trained is through this process called proximal policy optimization.
Okay.
PPO.
It's this idea that you have your policymaker, which is your LLM, that's like actually outputing
the language that gets output whenever you do the chat.
But then there's this thing on top,
which is kind of like the critic model.
And what that critic model is doing is it's during the training process,
it is taking the output of the policy,
which is the output of the model,
and then it's trying to guess at what the reward is going to be.
Okay?
And then what you can do is you can use this critic model
and the advantage that you get,
the advantage being what is my guess,
advantage at this particular strategy that's what this critic model calculates and
what this critic model does is feedback that advantage to the big LLM to tell it okay
you're on the right track the strategy is working or no it's not working
crucially this is very expensive because now you've got two models that you're
training right you've got two models and as the LLM gets bigger and bigger the
critic model has to get bigger and bigger to try to figure out how to calculate that
advantage in whatever scenario whatever game you're playing whether it's text
generation whether it's whatever right so if you've got a bunch of H-100s that's
fine right right if you've got billions of dollars of funding from random VC firms
that's fine but if you're deep seek that's no longer tenable so what these guys
did was they used a different strategy called group relative policy
optimization okay okay they don't have this second critic model that they're
doubly training
Right? They don't have this 2x parameter blow up.
What they have is their original LLM.
And what it's going to do is it's going to output a bunch of different answers.
Okay?
Let's say, for the sake of argument, let's say 10 different answers.
And then what it's going to do is it's going to calculate the reward for each,
which we can get because this is a reinforcement learning strategy.
And there's going to be a mean and standard deviation.
There's going to be a distribution that you can calculate about that.
10 different strategies.
There's going to be some that are above the mean,
which means that that is better than those others.
The whole idea is you're trying to get this idea of advantage,
which are the strategies that give me advantage
and which are the strategies that don't.
In the ones before, in the traditional LLMs,
the ones that we're doing in the States and in the West,
we've got this separate neural network
that is calculating that advantage
and telling the original one where to go.
Here, the original one is coming up with different answers.
answers and then creating a distribution out of that and then figuring out, okay, I should,
I should go here to this part.
Whatever I did here, that's what's good.
Whatever I did here, that's what's bad.
Because I came up with eight, ten different answers, these guys were bad, these guys were good.
Yes.
Right.
So you don't need this second giant neural network to train.
Right?
So it's a really interesting strategy where you're choked by the hardware.
Yes.
Well, I've got a few tricks up my sleeve.
Yes.
Right?
Yes.
I think it's rather cool.
I think that this is an important, you know, there is always because of this nexus between
nation states trying to accrue and maintain power and the importance of frontier technologies
to that goal, we're always going to see policy impact how these technologies grow and progress.
the Biden administration made a bet that hardware strangulation to China was the best path at creating advantage for the U.S. in the road.
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And it was a well-informed bet, right?
Because, like, everyone who had been doing AI
thought that that was the masterpiece, right?
The hardware was it.
Right? Ever since 2012,
when AlexNet came out.
And what they could do is actually use GPUs to train in parallel.
And then just all of the mathematics of matrix multiplication and back propagation
could be done on GPUs.
That's when it was, you know, ever since then, we've sort of taken for granted that, oh,
GPUs are really what matter.
But we've created good enough GPUs.
Yes.
That we've taken for granted that like the best GPU is always the best.
But actually the H-800 is like a good enough GPU now.
Yes.
that it can do enough of the math.
Yes.
That now these guys can actually go and, you know, start, start tweaking the knobs.
Yeah, start tweaking the knobs.
It's a really, you know, the cost difference is crazy.
The equivalence of efficacy of the models, given the cost difference, is even crazier.
And it is going to continue to be this, this hardware, software tension.
where do you innovate more?
Where has the most aggregate value
in terms of continuing to increase the power
and efficacy of these models?
It's going to continue to be a rolling story.
I think, again, to your point at the top of
when we started this story,
it is very interesting
that for the amount of time,
I remember using GPT2
in my company trying to see,
you know, trying to gauge
when is this stuff going to be ready for production.
years ago. And it is, the jury is not out yet on this journey to AGI and artificial super
intelligence, which of these two levers that we're pulling are going to create those incremental
because we've sort of seen the models are kind of starting to aggregate at a similar level
of performance.
Yeah.
And the gains from your walled garden are becoming less and less.
Yeah.
And this is a classic battle in every technology revolution that's ever existed in terms of
the tension between closed source and open source.
Yeah.
Open source has always been, you know, all servers run on Linux.
Yeah.
It's open source.
Why is that?
Everyone uses Python.
Everyone uses Python.
Open source.
And the reason the theory of the case is when you, you know, it's open source.
And the reason, the theory of the case is when you.
open source, there's more of a distributed incentive to create security.
Exactly.
Because everyone wants it to work.
You're having more viewpoints inputting into the system itself.
And you're limited by your resources, if you go close source, by your talent.
The way in which in the U.S. we deal with that is Facebook gives billion-dollar offers to the best AI researchers.
But at some point, this is a forever tension in technology revolutions.
And it's interesting to see it play out in this geopolitical.
sphere where the the winner or the the import of the battle is so high yeah yeah the stakes are
really high it's really high yeah yeah and so great first story I love the the AI story is
always great because a lot of times people just talk about the end product we haven't had a lot of
research papers to talk no but it's it's kind of cool that like you know we got a sort of you know
look under the box to see to see how it all worked and they and they were all
also forthcoming about some of the challenges that they had.
Like they, you know, when they, when they first started out with deep seek R10,
which is the one that they didn't release, they were having this trouble where like the output would be like half Chinese, half English.
Right.
So then what they did was they had cold start data.
So it wasn't completely all blind reinforcement learning.
What they did was they primed the model with human data.
Okay.
To actually sort of give it a running start.
Yes.
and not have it like from the very beginning,
start doing random stuff.
So what you do is you can have a small subset of human labeled training data.
Yes.
That like creates a sort of neighborhood of parameters.
Okay.
Where where, okay, like the model sort of settles in on this neighborhood
of where the numbers should be for all of these weights.
And then you can fine tune it.
And fine tuning is a coarse-grained word because obviously like a lot of training was done afterwards.
But like after that,
initial sort of like, okay, don't do like the stupid stuff of like half Chinese, half English,
but then now get into the, you know, how do you problem solve? How do you, how do you, how do you
actually make a really nice LLM? So, so they were forthcoming about some of their challenges,
which I think is, is kind of interesting. And again, it goes back to the sort of the narrative
violation that the current CCP has put ourselves in where in the U.S. we're still viewing their
operating system as what it was 20 years ago, but they are being nimble and understanding the
changing environment and trying to reposition.
Yeah.
Again, you can argue that it's contrived or not.
Yeah.
I mean, you know, knowing China, of course, there's stuff that we don't know about, right?
Of course, probably like, Deep Seek is entrenched with the CCP.
I'm just saying, you know, like, I'm just saying it's probably true.
But they're doing the work.
They're publishing peer reviewed.
papers, they're, you know, coming out with cutting edge AI and they're doing it without the H-100s
or at least not with the kind of access that, you know, companies have in America.
Perhaps they do have H-100s from shell companies in Bhutan or whatever, you know.
Which is one of the arguments is that they've been doing this illicit market trading in order to
access it. But the point is they don't even need it.
Yeah, yeah. It turns out like, you know, people are now that this is out,
they're going to try using these strategies now.
And we're going to see if the rubber meets the road.
And, you know, since deep seat came out,
Meadow was already releasing open weight models.
Yeah.
And they've continued,
I think they've actually incorporated some of the mixture of experts'
architecture into the llama models.
I think people are taking this sort of reinforcement learning strategy very seriously, too,
where they're saying, okay, maybe I don't need a bunch of Kenyans to just keep annotating my outputs, right?
Correct.
Yeah.
And we now, just in the last month and a half,
have an open source open AI model.
And it is very easy to argue
that we would not have an open weights,
open AI model without deep seek our way.
There was not an incentive for open AI to do so,
but they had to answer to investors
and the competition, et cetera.
Great, great update here.
We'll definitely be touching on AI more.
We're going to go to our next story,
which I'm very excited about,
because I don't know what any of it means.
Yeah.
The headline on our second story, scientists just made the first time crystal that you can see.
We have an ocarina of time.
Yes.
Physicists at the University of Colorado Boulder have created the first time crystal that humans can actually see using liquid crystals that swirl into a never-ending pattern when illuminated by light.
They put out their paper in nature materials.
There's been a lot of coverage of this one.
Yeah.
I always see all these TikToks.
I really love it.
Time crystals.
and all this.
Yeah, it's very Marvel, very Doctor Who.
Yeah, yeah, yeah, yeah.
Like, this is how we beat Thanos.
Mr. Strach, Dr. Strange.
Yeah, yeah, all sorts of, yeah.
So help me understand, you know, what exactly is going on with this time crystals paper.
Yeah, so, well, first, let's talk about what are time crystals.
I would like to know that.
Okay.
So before we even do that, normal crystals.
Okay.
We talked about diamond the other day.
Yes.
The simplest crystal I can think of is table salt.
N-A-L, sodium chloride.
You can imagine there's a sodium atom and a chlorine atom.
Sodium atom, chlorine atom, sodium atom, chlorine, chlorine,
in this regular sort of chessboard-like structure,
but a 3D sort of chessboard of sodium-chlorine, sodium-chlorine.
The reason why this is a crystal, right,
what characterizes it as a crystal is,
you've got a discrete space symmetry breaking.
Okay?
This is a technical term in physics that just means
if I take the crystal and I move it over by one spacing, I will get the same thing back.
Okay.
Okay?
You can imagine I've got the NACL and then there's another NACL here, right?
I can take that entire crystal and move it by a whole molecule and I'll have the same thing repeating, right?
Just like in a chessboard, right?
Imagine an infinite chess board.
That thing is a crystal in some sense, right?
It's a 2D crystal because there's black white, black white.
If I take up the chess board and I move it over two sort of squares, I'll get the same exact chess board.
Interesting.
Right?
So that's what's called symmetry breaking in space, okay, where it's no longer continuous because you can't just arbitrarily move this thing around.
You have to move it by the lattice spacing, right?
The lattice constant of the crystal.
Yes.
So that's what makes it a crystal.
And it's also resilient to forces and stress, right?
like a diamond, for example, great way.
I put stress on it.
The crystalline structure of the carbon atoms isn't really going to change
because the way that these carbon atoms are bonded to each other,
they're resilient to like push and pull.
You know, I heat it up that structure is going to be resilient.
Yes.
Right.
So there was a guy Frank Wilcheck.
He was a Nobel laureate.
He won the Nobel Prize in 2004 for discovering something called asymptotic freedom,
which has to do with the ways that.
that quarks behave inside the atomic nucleus.
We can get into that some other day.
I think we need some asymptotic freedom in the US right now,
but that's a whole other story.
That's a whole other story as well for another day.
But he won the Nobel Prize in 2004,
and he's been very active in physics ever since.
He's discovered things like called axions,
and like he's done stuff with cosmology.
And one of the things that he proposed back in 2012
was this idea of a time crystal, okay?
So he figured it's a very interesting, quite simple argument, okay?
He said that the laws of physics are symmetric to space translations, right?
Meaning if I do an experiment here and then I, you know, take up the experiment and I move it somewhere else,
the results of the experiment should be the same, right?
If all the environments are the same.
And that's because there's no special coordinate in the universe, right?
There's no like, oh, it's just like here is where where things happen, right?
There's no special spatial coordinate.
Well, similarly, the laws of the universe are also symmetric in time, right?
If I do an experiment now and then I do it the next day, it should be the same.
So if we have things that break spatial symmetry by creating crystals in space, right,
where you have clearly like carbon making the diamond.
or NACL making table salt.
So you clearly have spatial crystals.
What if I have a breaking of the time symmetry to create a time crystal?
And what would that look like?
What that would look like is you've got some kind of periodic system
that returns to its original form periodically.
Right?
So just like how with a space crystal, like the chessboard,
I can take it up and I can move it in space and then put it back
and it'll be the same thing.
In time, for example,
a sine wave, right? Mathematically, a sine wave is symmetric in time to that period, right? I can
pick up the sine wave, I can move it one entire period and put it back and it'll be the same
sine wave. Yes. I should be able to have that in like the physical world. Okay. Okay? Because, you know,
it's kind of same same. Yeah. theoretically, theoretically, it should be possible. And it kind of
makes sense. If I have the same sort of symmetry breaking in space, I should have the same
sort of symmetry breaking in time. Well, it wasn't quite that simple. Okay? Never is. So right after
he published that, it was, you know, Frank Wilczek is doing this. Nobel Prize one of his
very famous physicists. So everyone's like, okay, is this possible? And actually it turns out
the way that he had envisioned it, it is not. So people came out and they published something
called the no-go theorem for time crystals, which was that. Frank, Frank Wilczek's original
idea was that this time crystal is going to be in the ground state, which means it's in its lowest
energy state. There's nothing pumping on it. It's just, you know, crystals can be in their lower
energy state, right? I can cool a crystal down to like near zero Kelvin and it's going to remain
in its crystal form. And that's what really, like, that means that it's an inherent property
of the material itself, right? And it's not something that coming from outside creating this order.
Frank Wilczek's idea was that you can have a system that is in its ground state, right, in its lowest energy state, there's nothing coming in, and it's still going to behave in this sort of periodic manner.
Yes.
Okay.
That turns out can't be the case.
Okay.
Okay.
So the no-go theorem said that a true equilibrium ground state cannot have persistent periodic motion.
Meaning, like, if you've cooled something down to its ground state, it's going to be stationary.
Right.
And that kind of makes sense, right?
Because if it's moving around in its ground state, that means there's some kinetic energy that I can extract.
And it's not really the true ground state.
Right.
Okay.
So that's fine.
But then people started wondering, all right, fine.
I don't need something to be an equilibrium at its ground state.
What if I pump it with stuff?
Can I create a crystal that way?
What if I pump it with energy?
So it's now a non-equilibrium state.
Like there's energy coming in and then there's energy going out.
But the way that this energy is transformed in.
the system creates this periodic motion within the system, right? Turns out that was possible.
Okay. And for the longest time people were studying these things called discrete time crystals.
They were systems that were kept out of equilibrium by this outside force. And it's not as simple as just like you just pump it rhythmically and then this thing
Rhythmically, you know, then it's like, oh, like me on a swing like doing my legs is a time crystal.
Right? That's what I'm going to say.
No, no, that's not, it's not quite as simple.
Okay.
What you need is you need, you need the, the pumping to be done at a certain frequency,
and then the crystal itself is doing it at a different frequency.
Maybe it's at a harmonic, right?
Mm-hmm.
And there were specialized quantum systems that could do this, right?
There were nuclear spins, trapped ions, cold atoms at extremely low temperatures,
quantum weirdness.
You know, it's like cool.
Yeah, but it's cool.
Yeah.
But that's about it.
Yeah.
Like maybe in 100 years, it can lead to like, you know, quantum devices and things like that.
This paper is very cool because it's doing it in a classical system, which means no quantum weirdness.
And it's doing it at room temperature.
Wow.
And it's doing it at a big enough scale that we can see with our naked eye.
This is giving me LK99 vibes.
Yeah, but this is out of UC Boulder.
Yeah, so it's legit.
And so it's pretty legit.
UC Boulder has probably the best.
AMO department out of anywhere in the world. Okay. Okay. Atomic molecular optical. Those guys,
those guys do it. Let's invest in our university research institutions. I mean, you know,
Boulder has like the most PhDs out of any, out of any city. I heard this recently. Yeah. And a lot of it
has to do with UC Boulder. Out of UC Boulder came NIST, which is the National Institute for Standards
and Technology. There's a bunch of other science labs just in Boulder. UC Boulder itself has like
four Nobel Prizes in physics just for AMO. Okay.
Like, not like, okay, there's one for cosmology, one for, it's just all like in the lab making like materials, right?
They made the first bosonstein condensate.
They're the ones who figured out how to trap ions using lasers and cool them down using lasers.
So they're a very good.
So when a paper comes out of UC Boulder and it's an AMO, it's like, okay, these guys probably talk to their department.
And if it didn't pass like their own.
Yeah, they have the best in the world there.
Yeah, yeah, yeah.
It's like, so.
So it's, it's a really cool.
little thing that they've made out of liquid crystals, right? These are the LCDs. And they made a
macroscopic time crystal. Okay. The and and what you can do is what's really cool is first of all,
you don't need a laser or oscillating magnetic field like in those old time crystals. In the old
ones you needed a quantum system and you needed a laser which means coherent light,
single frequency and then you or like a magnetic field it's oscillating at a single
frequency and then that sort of drives this quantum system to do this periodic motion.
This is just like a light.
You just shine a light on it and then it uses the energy from that light to create this
periodic motion.
Okay.
And it just uses LCD like liquid crystal technology, pneumatic liquid crystals.
So the way that liquid crystals work, like you know, you've used liquid crystals before,
it's a really simple technology.
It actually won the Nobel Prize.
the idea is so what does it mean by a liquid crystal okay a crystal you usually think of as a solid
yes right a solid meaning that you've got atoms in a regularly spaced pattern and they don't really
move in the liquid crystal you've got molecules that are all sort of you can think of them as like
rods many tiny rods there are molecules that are elongated and you can manipulate their direction
using an electric field.
Okay.
So if you put an electric field in this direction,
all of the molecules align in that direction.
And you can have an electric field in this direction,
which means all the molecules align in this direction.
And what these molecules do is,
because they're small enough,
they can actually influence the propagation of light.
Okay?
And so that's exactly how liquid crystal displays work.
What you do is you have a back light, okay?
That like lets, and then you have a polarizer
that polarizes all the light.
all of the electric fields are propagating in one direction.
And what you can do is you can have a liquid crystal interface in between another polarizer.
So now, if the light gets to the other polarizer and it's polarized in the same direction,
it's going to be let through.
But if the light is polarized in a different direction in the perpendicular direction,
then it's going to be blocked.
And what you can do is use an electric field to manipulate the liquid crystals in the middle
to influence the propagation of light.
on the other side.
That's the fundamental technology.
That makes sense.
Okay?
So you can have an electric field that sort of rotates the light.
And then if it rotates in exactly the right way, then the light is going to go through
and I'm going to see something.
But if there's no electric field or if I make the electric field this way, then all the rods
are going to be, you know, sort of in the perpendicular direction.
The light is not going to rotate and I'm going to get blocked.
Yes.
And that's fundamentally how liquid crystals work.
There are these, they're liquid in the sense that, you know, just how in a liquid the molecules
can move around.
In this case, these liquid molecules, these rod-like molecules, can move around, and they can
be controlled by an electric field, and they can be controlled by light itself, right?
Yes.
So they figured what I can do is I can create a liquid crystal, and this liquid crystal
has exactly the right properties where it can sort of act like a giant sort of...
I guess, okay.
So this liquid crystal can be oriented in such a way that when it's shined on by light,
what you're going to get is deformations in the crystal, okay?
Tiny little deformation.
So what you can imagine is, let's say all of the liquid crystals, all of these rods are oriented in one direction, okay?
And now what I do is I introduce a tiny kink in this lattice.
So they're all oriented in one direction, but I've taken like a tiny little neighborhood and I've like bent them in a certain way.
Okay.
What you can do is create a material such that that bend, which becomes this sort of topological defect.
Yes.
This idea of like, okay, this neighborhood has a tiny little bend or a twist.
That twist can then influence the stuff around it, which can influence the stuff around it, which can influence the stuff around it.
And what you get is this sort of traveling wave of disturbance.
Yes.
Okay.
There are what are called topological solitons in physics.
This idea that I've got this like disturbance and that disturbance kind of acts like a particle.
Okay? Because it travels the same way as a particle.
The orientation of that disturbance can have a charge in the sense that if I twist it clockwise, then it's a plus one.
And if I twist it counterclockwise, it's a minus one.
And that charge is conserved in the same way that sort of charge is conserved if I were to have like electrons moving around, right?
And they can cancel each other out, kind of the same way the charges cancel each other out, right?
So they created this thing and they actually did the numerical calculation.
So they wrote down an equation for how these solitons would interact with each other.
And all of these deformations act like little quasi-particles that interact with each other and have a physics to themselves.
that is an emergent property of the little tiny rods themselves.
That initial disturbance that has now created a cascade.
Yeah.
That is now independent of the initial source necessarily being.
Yeah.
And it's like it's on top of the rods themselves.
The rods actually aren't the particles anymore.
It's like the way in which the rods are oriented becomes a particle mathematically.
Right?
You can like describe like you can describe the twascribe.
twist itself as this thing that propagates rather than the rods.
Because the rods are just staying where they are.
Right.
Right.
Right.
Right.
But the way that the rods move, that disturbance moves around like a particle.
This is really.
Which is kind of cool, right?
No, it's very, that's like very interesting.
Yeah, dude, solitons have been around.
Like, I think in the 1800s, there's this British guy.
Forget his name.
Maybe we'll put it up.
Yes.
But it's a funny story because what he saw was, he was,
He was, you know, these British physicists back in the day were very rich, right?
So he's on horseback in the countryside, right?
And he's like, he's like on horseback and he sees a canal and then there's a boat.
And the boat like breaks suddenly.
Okay.
And when the boat breaks suddenly, it created this wave.
And he noticed that the wave just kept propagating.
And then he was on horseback and he's got nothing to do.
He's probably, you know, got an estate that like gets him money like in Downton Abbey or whatever.
So he's like, fuck it.
I'm going to follow this wave.
and he followed it for two miles.
There was a wave that kept reinforcing itself
and it acted kind of like a particle, right?
In the sense that the wave didn't really dissipate
until two miles later.
And he could follow this thing and he discovered the first soliton.
There's a little plaque where he lived,
where it's like this is the guy who discovered the first soliton.
And ever since then, they've been observed in all sorts of material sciences.
We've observed them in biology and quantum systems.
And this is exactly the way.
one of those things where it's like there's a wave that's being propagated and that wave sort of
reinforces itself because of the way that the the medium itself works works right now right it's it
is a combination of that input and the structure of the medium yes exactly the liquid crystal
yeah and the structure of the liquid crystal crystal enables it to continue the propagation
of the wave independent like as as a as an as an as an emergent property of the structure's
initial condition. Exactly. Yeah. Yeah. And so they figured that they could use this to make a classical
time crystal. Right. Because this is not quantum. This is, this is just, the rods themselves are like,
you know, multiple, many, many atoms big. Right. So these guys are interacting through just classical
effects. Yes. Right. And so what you can do is you can have a liquid crystal embedded inside glass,
right, that have these two layers. And as one layer sort of moves, it influences the light on the other layer.
And that thing moves.
And there's this feedback cycle, right?
And that feedback cycle is what creates this propagation of the time crystal.
And it's really a space time crystal because what you're seeing, you can actually look at the videos.
And you can see like this, the colors move in real time.
And the wavelength is like, you know, about half a millimeter to a millimeter, which means you can see it with your naked eye.
And it's moving through this liquid crystal.
in this sort of propagating, you know, traveling wave, right?
And it was huge because one of the, one of the big things that defines a crystal, right, is it has to be, as I said, before, crystals have to be resilient.
Yes.
To stress.
Right.
Okay. If I take a diamond and I press it or I heat it up, the diamond is going to retain its temperature.
So how did they actually test that here?
Well, what you can do is you can like poke it.
Yeah.
And the, the pattern stays.
stays, which means that it is a true time crystal. Right. It is resilient to the
poking of it already has. Yeah, it's got some time crystal going through and then when I
poke it, the time crystal sort of like it recovers where I poke it of course it's going to like
mess up but I remove it and then the the crystal regains its properties. Yes. The other thing
they did was they would vary the brightness of the light. Yes. Because it can't be that like,
you know, it depends really heavily on the brightness of the light. So they they randomly
varied the brightness of the light, the crystal kept going, which means that what this is is really an
intrinsic property of the material itself rather than the drive that's coming from the outside.
Yes, yes.
No, that's a very, that's exactly.
Yeah.
And then the final nail in the coffin for me was, what they did was they would turn off the
light and then they would turn it back on again.
And if this is not a true crystal, if this is simply a response to the light, then when I
turned it off, I mean, sorry, when I turned it back on, the crystal would start up at exactly the
same phase every time, meaning I turn it on five minutes later, the same pattern, I mean, sorry,
five seconds later, the same pattern emergence at exactly the same spot. But what would happen was
they would turn it off and then they turned the light back on and it would randomly order itself.
The same crystal would start, but at different starting points in that way. You see what I'm saying?
Like the phase offset was completely random.
Yes.
Which again tells you this is not a property of the outside drive.
Right.
It's a property of the material itself.
So this is truly a time crystal that is macroscopic and it's something we can see.
This is, I mean, this is so, right?
This is really fascinating.
It's really cool.
And like, okay, you might be thinking, okay, this is, like, this is cool, right?
Then I got into reading about the applications.
Okay.
Okay.
The applications for this are like science fiction to me.
Okay.
Most of them have to do with like cryptography and security.
Okay.
First one I'll tell you about, imagine we make this thing cheap.
We can stick it on a dollar bill.
Oh, right.
As a cryptographic signature.
As a cryptographic signature.
Now, if you want to test whether your Benjamin is a real Benjamin, you take your
iPhone flashlight, stick it on there.
It's going to have this pattern, right?
Because all it needs is an external drive.
And the pattern is we can make it really hard to duplicate.
Yes.
Right.
So you know that strip that's on the Benjamin.
Yes.
We can have that strip be a time crystal that like literally like propagates.
Yes.
Right.
And then you'll know, okay, that's a real one.
It has a signature that only.
And it's going to be so hard to duplicate.
Right.
Right.
That's so cool.
No, that's very, that's actually really.
Yeah.
And the other.
The other one is like 2D, like so, you know, usually we have 2D barcodes, like a QR code is a 2D.
Now you can have a 2D plus one barcode.
You can have, you can have a QR code that is 2D.
And then when you shine a light on it, the QR code itself changes into different QR codes.
You can have multiple QR codes on top that have different periodicities.
So that like, let's say one is like two seconds.
and the other one is three seconds and the other one is five seconds.
Well, then the next time that it's going to become a full QR code is going to be five times three times two, which is 30, right?
So you're going to have to wait 30 seconds to get the actual QR code, right?
You can imagine you've like you've introduced a whole new dimension.
Yes.
To security.
A manipulatable dimension.
Yeah.
And the whole point is this is at room temperature.
Right.
And it's macroscopic.
It's something I can see.
I don't need a telescope or like weird ions and lasers to actually, oh, look, it's doing the thing.
This is why I made the LK99 reference, not because of whether it was real or not real,
but because it's room temperature and macroscopic.
Yeah.
And the reason why that's material is that means the transition from theoretical to production application.
Yeah.
Now we've just got to make it cheap, which is honestly kind of like the easy.
like the easier part of the innovation, right?
Exactly.
You know?
It's an engineering problem.
Yeah,
now it's like,
okay,
because we can make LCDs real cheap now.
Right, right, right.
This is.
And like this,
this,
you know,
it's not,
it doesn't need a power source.
You just need to put it on there.
The power source is the light
that I'm going to shine on it.
It's kind of cool.
I'm seeing from the,
from the abstract here.
Their potential technological utility
includes optical devices,
photonics,
space time crystal generators,
telecommunications, anti-counterfeiting design.
Yeah.
And again, this is just a first.
We haven't even thought.
Yeah, I mean, I only talked about the anti-counterfeiting and the security part.
But yeah, as you said, devices.
All sorts of.
There's all sorts of implications in terms of what we can get out of now this fundamental,
like implementation experimentally at room temperature in a macroscopic form, which is.
Yeah.
I mean, there's a reason why it was like picked up by so many news outlets.
Yeah.
It was like, yeah, it was cut by.
This is quite a big deal.
This is quite good.
They didn't get the, they got nature materials.
They could have put it in nature, but they said, yeah, we put in nature materials.
They probably tried in nature first.
Usually everyone does.
First time crystals that you can see, really interesting story.
And the background is also helpful to understand.
We live in L.A., so we know a lot of people that like to talk about crystals.
This is a little bit different than those crystals.
Yeah, this one actually works.
Speaking of California.
for our third story, we're now going to move into the immunology space.
Headline, hidden viruses in our DNA could be medicine's next big breakthrough.
Scientists at La Jolla Institute for Immunology, when they're not out surfing on the beautiful sand beaches of San Diego,
have decoded the 3D structure of an ancient viral protein hidden within our DNA.
Our own DNA.
Our own DNA.
This protein found on cancer and autoimmune cells has a unique shape.
that could unlock new diagnostics and therapies.
This was published in science advances.
Again, this is another California University.
We have the most papers, the most patents, the most laureates.
I just always have to make sure people know that we are winning.
We are winning.
We are winning.
This is La Jolla, California, baby.
Yes.
It's right next to UC San Diego.
UC San Diego is an amazing, amazing crucible for biotechnology.
and molecular biology research.
It's kind of like the Silicon Valley for biology in some sense.
And this is a really groundbreaking achievement.
It's the first time that we have ever published the structure of a human endogenous retrovirus.
Okay.
And this is a virus that hides within our own DNA, UNRs.
I didn't even know that was possible.
Yeah.
This is crazy, dude.
8% of our DNA is viral endogenous DNA.
8% of our DNA.
You know, approximately 98,000 annotated insertions are viruses that are like infiltrating, that have infiltrated.
Dude, it's, it's, they're like, they're like sleeper cells, dude.
I was, this is when people say the aliens, uh, manuf, uh, created.
No.
They would argue.
Look, this is exactly what I'm talking about.
Yeah.
No.
Like little viruses are there writing our stuff.
It's crazy.
It's crazy to think about.
So, so, so first of all, I was like, I was like, how does this even get in?
Why is this in my DNA, bro?
Right.
Like, what, what's going?
going on? Okay, so it's crazy. These things are called retroviruses. Retrovirus is a virus that has,
instead of using DNA as its genetic material, it uses RNA as a genetic material. And what it does
is when it infect a cell, it uses something called reverse transcriptase. Usually transcriptase
goes from DNA to RNA. This is the reverse process. So it's taking RNA and it's making double-stranded
DNA. So that's reverse transcriptase. And then what it ends up happening is that reverse transcriptase,
reverse transcriptase goes inside the nucleus of our cells.
Yes.
And then there's something called Integrase, which is another viral protein that takes that
DNA, that bit of viral DNA, and sticks it inside our chromosomal DNA.
Now, if this happens to our skin cells, okay, we got like some viral DNA.
But if it happens to our sperm and egg, now the next organism that gets that sperm
and egg, all of the DNA has it.
It's going to have it, right?
These are called germline mutations.
I was literally saying it's kind of going back to our CRISPR story.
Yes.
It's the germline mutations, right?
Yes.
So this is a germline insertion that happens.
And then now the virus becomes something called a pro virus, which is something that's just hanging out in our DNA.
Yes.
8% of our DNA comes from this.
Comes from this.
Dude, that's one in 12.
That's like a lot.
That's a lot.
That's a lot.
I had no idea this was even a thing.
Right?
Yeah.
Yeah.
This is crazy.
I was like, this is fascinating.
Yeah, yeah.
So all of that junk DNA, 8% of, 8% of.
of that is is is viruses just hanging out okay now most of these viruses they get mutations
over the years and they become inactive okay but there's a specific um virus called the human
endogenous virus k the herb k virus okay it's a pro virus now because it's within our DNA but this
thing is the most recent infiltrator okay and it's because it's the because it's the most recent
infiltrator it has the fewest number of mutations right which means it's still a problem
Okay. And it actually, so in most, in most healthy cells, there's epigenetic silencing, okay?
Our DNA has figured out, I don't know who you are. I'm going to, I'm going to just put a bunch of, like, random stuff on you.
Yeah. So, no one ever transcribes you into RNA and then you become a protein. Okay. So our DNA is very good. If you're healthy, the cell is healthy. It's like, I don't know what this is.
It's like a bouncer at a club. Yeah. It's like, you're already in here, but you're cut off.
Yeah, yeah, yeah.
You know?
I don't know how you got in, but no more drinks.
Okay?
Every once in a while, you get something like a cancer cell, or you get autoimmune disorders.
The cell is losing control, and this virus can start acting up.
Okay?
So it's actually been detected this H-Herve-K envelope, the envelope protein that is the protein that encodes for the envelope of the virus.
That's the thing that's snuck in.
Yes.
Right.
That has been known to be expressed in cancers, like breast cancer, ovarian cancer, prostate
cancer, melanoma, and also in autoimmune disorders, like lupus, diabetes type 1,
SLE, these kinds of autoimmune disorders.
You can actually see the cells that are affected express this Herb K protein, which means
that it is actually a problem.
Okay.
Right?
Which means it needs to be solved.
Yes.
Okay?
And in biology, like half the battle.
is solving the structure.
Right.
Because all of biology is lock and key, right?
You solve the structure of the thing,
then you can figure out what other structures can latch on
and, like, mess with it and, like,
inactivate it and things like that, right?
So the first battle is to actually solve the structure.
Solving the structure for this thing was really hard.
Okay.
Because it's this envelope protein of a, you know,
it used to be back in its heyday, right,
before it snuck in and now it's like just like an infant,
infiltrator. Back in its heyday, it was the envelope protein for a retrovirus, right? And these
envelope proteins are incredibly finicky. By design, you want your envelope protein to be finicky
because imagine you're a virus, right, and you're getting to the outside of a cell that you
want to infiltrate. You want the protein to first be able to infiltrate through the membrane,
and then when it's in the membrane, change its confirmation to open up, right?
So you want this thing to have this sort of metastability is what it's called where you've you've got two states
There's this pre-fusion state and then a post-fusion state, right?
Pre-fusion meaning like how do I get in post-fusion? How do I?
You have the Trojan horse go to the gate in one state and then when it's inside the gate it's open up.
Yeah, right?
So you want this metastability.
Now that becomes a real problem when you're trying to get structure.
Yes.
Right?
Because you can imagine you're trying to image this thing, but this, this, this.
thing is in two different confirmations so like you don't know what you're looking at
yes and it's just annoying yes right so that that's the the big thing that this group
solved okay what they did the first thing they did was they took the the protein itself
and they put in um they they tweaked the protein in a certain way that they could
like they created these things called disulfide bridges which are basically like
staples on the protein what you do is you create you put in cissy
cysteine, which is this particular amino acid that has sulfur atoms, and those sulfur atoms
can find each other and sort of bond.
So you create a more stable protein that is still very much like the original protein.
It still preserves a lot of the structure, but it prevents the protein from doing this finicky stuff.
And then what they do was they use a groundbreaking technology, the one the 2017 Nobel Prize in
chemistry called cryoelectron microscopy okay okay it used to be called blobology
blobology yeah from all the detractors all the people who would make fun of these cryo
em people it was called blobology because back in the day what you do is you get a protein and
you like image it with electron microscope yeah but because of this problem of like you know the
the proteins move around and then they're not stable and all this other stuff um and
you would get blobs, giant blobs, and you'd be like, it kind of looks like this.
So all of the x-ray crystallographers and the NMR spectroscopy people, they're like, look at these,
blobologists, right?
Because with X-ray crystallography and with NMR, I can get down to atomic resolution.
I can get to two or three angstroms of resolution, where I'm like, that atom is there and it's
there.
The problem with X-ray crystallography and NMR is it's really good for soluble proteins, so
proteins that are found within the cell doing their thing.
But for these transmembrane proteins, it's very hard to crystallize.
It's very hard to make them behave properly.
Cryoem was a technique that probably could have been used for that.
Along came the computing revolution.
And now all of a sudden what you could do is you could take thousands of images in cryoem.
What you do is you have a bunch of proteins that are sort of frozen in this state.
Yes.
using this thing called vitreous freezing,
where you're not like freezing it with ice,
because if you freeze it with ice,
the protein is going to like miss forward, right?
So you do this weird, like,
sort of vitreous freezing where the protein retains its structure.
You image it a bunch of times,
and then you feed that thing to a computer.
Yeah, yeah.
What you're getting is 2D shadows, right?
The proteins are in different orientations.
You get a bunch of 2D shadows,
but a computer now can take all of those 2D shadows
and say,
what is the 3D thing that would create all of these 2D shadows?
Right.
Right.
In 2012 was the big one when it came out.
And there was finally a protein that cryo-yam had solved that no one else could solve with any other technique.
And they solved it to three angstrom precision.
And everyone was like, oh, oh, it's here.
And then in 2017, they won the Nobel Prize in Chemistry.
It was three guys, Joaquin Frank, Yakes Dubose, and Richard Henderson.
So Blobology now became like a Nobel Prize winning technology.
Ain't no bunch of blobs now, huh?
Yeah, exactly.
Where's your Nobel, huh?
I think they were very vindicated when they actually got it, right?
So these guys, they actually used the cryo-electron microscopy to get the data from this.
After having messed with the protein to create these staples and make it sort of stable, right?
And this was a very big deal, because now you've got the 3D structure for this thing.
You can compare it with other retroviruses that have been solved like H.
HIV like SIV.
Yes.
And this one is very different because this, the, the, the, the, the protein that
came out is like taller and skinnier than the HIV protein, which is interesting
in its own right, because now we've got this difference.
We can now start creating antibodies right to actually target this thing.
This blocking key thing you were just talking about.
Exactly.
And that's what they did.
They weren't done.
They created monoclonal antibodies to actually target this thing.
And what they could do now is you can actually have diagnostics where, you know, you
No, in autoimmune disorders, for example, right?
You have these neutrophils, which are these kinds of immune cells.
And what they do is they're expressed in these cells.
And then in an autoimmune disorder, now your immune cells think that, oh, this is a bad cell.
I'm going to attack my own cell, right?
So maybe now that we know the structure, we can actually like prevent that from happening.
Right?
We can train the immune system or maybe cloud the.
these antibodies in such a way that the immune system no longer attacks its own.
On the other hand, we can also have ways to early diagnose certain cancers because cancer cells
express this protein specifically.
Specifically, right?
So if we get like a blood sample from somebody, we can have an early diagnostic where
you have these monoclonal antibodies that'll go and actually attach to these cancer cells
and you'll have a marker now.
Be like, oh, I see this Herf K protein.
that shouldn't be expressed.
In a healthy cell, the epigenetics should totally silence it.
But the bouncer is not working, right?
Right.
So now I can start therapies earlier.
They're still in the club getting too drunk.
They haven't been cut off.
So let's go ahead and say.
Let's go ahead and try to figure out how to get these guys out.
That's really.
Right.
It's the first time that we've done this.
And the idea is now that we've done it once,
by confirming that this methodology is a means by which you can do so,
Yeah.
This can likely be extended to other ones.
This is the most recent and all these.
Yeah.
And this is the one that's like most prevalent.
But the idea of like sort of changing a protein shape using these editing mechanisms where now I can have this like staple disulfide bridge that sort of stabilizes it such that I can now do cryoem.
Yes.
This is a this is a pretty interesting technique.
Right.
The same group actually had done it for other proteins.
And then they tackled this one because this one's hard.
Yeah.
Right.
This one's like.
If you can do it with this one.
one. Yeah. Then it's like, okay, now it's like a, yeah, now we can, um, fast.
This is, yeah, it's a cool one. I, I, I, I always love our, are, are like, microbiology,
immunology stories because people don't understand how well we can, uh, look at and analyze and
understand things that are really, really, really, yeah, dude. Yeah. Like, we can, we know exactly
where to put in the cysteine. Right. So that the sulfur staples to another sulfur, but it doesn't
really change the rest of the structure.
That's like to, you know, have like this thousands of atoms worth of protein and know exactly
where to put this thing so that I'm just going to clip this part.
Yes.
Because that's the part that's like getting messed up.
I would like our next Department of Health and Human Services Secretary to be able to describe
in detail any number of these concepts.
Yeah.
Because that is usually a good prerequisite to say you're going to actually understand the import.
of medicine for public health.
Exactly, mate.
But that's a good, I like that one.
I like that one.
And we've touched on CRISPR a lot on this podcast.
We've touched on a variety.
And it's, again, it's interesting.
Again, all of these innovations are happening simultaneously in these cross-domain areas
that have not only independent value, but also like collective value.
As we move into what we're seeing is going to be this like biotech revolution.
It is.
It really is.
We're here.
For whole AI applying the tools, the fundamental hardware tools, the creativity of how we're problem solving.
We're going to go to our last story, which is a lot of times we can do from really, really small now to like.
Now we're getting really big.
Now we're getting really big in space.
California again, California Forever Goodbye.
Headline, brightest fast radio bursts ever detected could help solve an enduring cosmic mystery.
of how people with headlines make it so unclear what you're talking about.
Summary, researchers at University of California, Santa Cruz,
we're going to Northern California,
use newly developed chime-out-trigger telescopes and deep space imaging
to challenge long-held assumptions about what causes these mysterious cosmic signals.
I think we talked about one of these, if I'm not misremembering the wow signal,
was one of these, like, radio bursts things.
It was a radio burst, right?
We initially saw and everyone freaked down and was like aliens.
Yeah.
It could have been.
And that's not the, we haven't characterized that as a fast radio burst.
Fair.
Because we don't really know what the hell that was.
That's fair.
What was that?
Yeah.
What was that?
Fair.
No, that's fair.
That's fair.
But it seems like we're now using, again, the tool, some of the tools we have.
Also, this was in the astrophysical journal letters.
Yes.
In terms of the publication, CNN has covered this.
UCSC also covered it in their own blog.
Yeah. It's a collaboration between UCSC, some Canadian institutions, Northwestern.
It was a pretty big collaboration.
That's, again, because we need it.
Okay. So what are, because I mischaracterized, what is like this fast rate of burst idea?
What did they do?
Yeah.
Like, how are they, why is detecting a bright one relevant?
Yeah.
This one's incredibly bright, okay?
This thing, this thing within a fraction of a second output, as much,
energy as the sun does for like four days.
Okay.
But this isn't even the brightest.
Okay.
This is the brightest we've had because it's the closest one to us.
But fast radio bursts, the first one was ever discovered in 2007.
It was called a Lorimer burst.
It was actually taken from archival data from the Parks Observatory, which is a giant
64 meter radio telescope in Australia.
It's been called the greatest scientific instrument that Australia has ever produced.
The greatest scientific instrument that Australia has ever produced.
And the same dish actually was used during the Apollo 11 broadcast to like broadcast to the TVs around the world.
Because NASA had like a thing at Goldstone that they were using.
But this one was way bigger.
And the TV signal that they were getting from this one was just better than the rest.
And so the NASA just used it for the whole two and a half hours, which is kind of cool.
Which is why the Five Eyes ally, you know.
Yeah, yeah, you know.
Yeah, Australia, yeah.
They got our back when we need it.
So, you know, they were on the right side.
They were facing the moon, so that was nice.
Yep.
So this burst was discovered by Duncan Laramar from West Virginia University.
Basically what he did was he assigned an undergrad to look at archival data from the Parks Observatory.
Okay.
And the Parks Observatory at the time had just released a bunch of data.
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It was a radio telescope that was just beaming
up and this undergrad would come in every week and despite all of his classes and stuff he would
look at a bunch of data by hand and try to characterize it and then try to find something interesting
and he found something very interesting there was a brief millisecond duration five milliseconds
but it was ridiculously bright on top of that it was not only bright it had this very good
characterization called dispersion okay dispersion is the idea that when like like
moves through a medium through stuff different frequencies are going to
propagate at different speeds this is fundamentally why we get a rainbow okay violet
light actually propagates at a slower speed in water than red light does okay
and because of that when light goes into a water bubble the violet light is
gonna bend differently than red light and that's what's gonna cause the
rainbow to come out okay and then it gets like sort of focus
and we get a rainbow. But the prism is the same idea. When it goes through glass,
violet light goes slower and so it's going to bend differently. Dispersion is this idea,
that there's a frequency relation to how fast light moves through medium. And in interstellar
background, right, in the interstellar medium of these ionized particles, right, where it's like
atoms without electrons, electrons moving around freely, you're going to have that opposite effect.
You're going to have slower light, so slower frequencies moving slower than the faster frequencies.
It just has to do with the different physics that goes on between a glass and a plasma.
But at the end of the day, what that means is if there's a transient burst of light, the faster stuff is going to arrive first, and the slower frequencies are going to arrive later.
And that's what's called a dispersion measure.
Okay.
This thing that they discovered in the Parks Observatory data, which is now called a Lorimer burst,
had this very specific dispersion measure, which showed that it was of extragalactic origin.
Okay.
There was so much dispersion that meant that there was a lot of stuff that it had to get through.
To actually create that delay between the fast and the slow.
And then when they back calculated how bright this thing must have been to be that far away.
Right.
They were like, oh, this thing was incredibly bright.
This was back in 2007.
Since then, we've discovered multiple.
there's been some that we've discovered
where for that brief
millisecond duration
this fast radio burst was
brighter than the entire galaxy that it came from.
Wow, okay.
Okay?
Yeah.
So it's been, it's been,
it's been quite an insane
sort of last few decades
of trying to find these fast radio bursts.
Right.
The problem is they're really short-lived.
Right.
Okay, five milliseconds.
Unlike three-eye Atlas,
which we're watching for a month.
Yeah, yeah, which we know for months
and we can like coordinate
This thing, you know, it's just, it's there and it's gone.
And it happens.
And it just so happens, right?
So it's been, it's been kind of challenging to actually find them.
Right.
It's been kind of rare.
Along came this detector called chime in Canada, which is the, let me just get the thing right
because I don't want any Canadians to get mad of me.
It's called a Canadian hydrogen intensity mapping experiment, chime.
It's a massive radio telescope.
that doesn't look like most radio telescopes.
So, you know, most radio telescopes,
you've got a circular dish with a receiver
and the light goes that way.
This thing is a bunch of half pipes
that are just laid out on the ground.
Oh, interesting.
Giant half pipes, okay?
100 meters that are laid out on the ground,
four of them in a valley in British Columbia,
as south as you can possibly get
because what they're using,
they're using the Earth's rotation
to basically scan the sky
in this radio frequency.
Yep.
And, you know, Canada's pretty far north.
Yeah, yeah.
So they want to get as south as possible.
So it's like right across the border from America.
And it's this giant thing.
And it's made such that it's really sensitive.
It's got all these capabilities for as soon as a signal comes in.
It's kind of like the Vera Rubin in terms of they've got online capabilities to analyze the signal.
And it's also got a really good giant field of view.
So it's capturing a big part of the sky as it sort of goes around the earth.
And very recently, so Chime has.
Chime has found thousands of fast radio bursts since 2018.
Okay.
Okay.
It's found a bunch.
This one is very, very nice because usually when Chime finds fast radio bursts, it can't
localize where it came from.
Right.
Because it's got this giant field of view, it just sees sort of a signal.
Yes.
And it's like, okay, I saw a fast radio burst.
You don't know where it came from.
So what they did was in collaboration with America, they made more Chime stations.
There's one in California.
There's one in West Virginia.
There's one also in Canada.
And now what you can do is triangulate.
My favorite.
What you can do is if you get a fast radio burst,
you're going to get that signal all over the place.
And you can triangulate where it came from
and actually resolve what part of the sky it came from.
Because you have multiple receiving points
at different places on the planet.
Exactly.
The angle is going to be different.
And the timing is going to be different.
And you can back calculate and see where it came from.
And what they could do is they could resolve it.
it to a really tiny area in the sky, right around the big dipper.
The equivalent would be to resolve a quarter from 100 kilometers away.
Very tiny, very tiny, tiny spot.
Right?
And that gives you the advantage.
Because now, if you know that it came from there, you've got all these other telescopes on
standby that can point right there, right?
That's exactly what they did.
They got the James Webb.
They called in the big guns.
Yeah, they called in the big guns.
They called in the big guns.
Because this one was really...
bright. Okay. In terms of, this is the brightest fast radio bursts that we've ever seen
because of its proximity to Earth. Not in terms of intrinsic brightness, but because of its proximity
to Earth, now it's really exciting, right? Because now we can point optical telescopes to it
and we can actually see what part of this galaxy that it came from. It came from NGC 4141, which
is this barred spiral galaxy. And what it does is, and you can localize the neighborhood
of that galaxy, not just that it came from that galaxy,
but it came from this corner of the galaxy.
Okay?
And now you can point James Webb's space telescope to it,
and James Webb was pointed to it.
It found a faint signal in the infrared.
Okay.
Right around that same spot.
Okay.
And that probably came from some massive stars,
like a red giant or something like that.
Now, it doesn't quite fit that a red giant or a big star
would create a fast radio burst.
Okay.
Okay.
Because those things are like slow.
Right.
They're not five millisecond.
Right.
Time scales.
Right.
Five millisecond time scales are the stuff of black holes.
Right.
Neutron stars.
They revolve really fast, you know?
So there's timescales that sort of correspond to astronomical objects.
Yes.
Right.
And so now it leaves us with a conundrum.
It's like, where did this thing come from?
There's hypotheses.
There's not good data.
Because again, this is the first.
I mean, Chime and the Chime Outrigger stations only came online like this year.
Okay.
So there's the first thing that it's found.
And it's very exciting because it's kind of a proof of concept that it's like looking
and it can find it.
And then we can go off with James Webb Space Telescope, with Keck, with Gemini, and
pointed at that and then actually see a follow-up observation, right?
So we still don't know really where this thing came from.
What we do know, which is very interesting, is this might be a,
one-off. Most of the fast radio bursts that we've seen, they seem to be repeating fast radio
birds, right? Where they've got this rhythmic sort of structure. The rhythm can be very long.
It can be from days to months to years. But they've got this rhythmic thing where it's like,
okay, you've got one really bright one. But then every once in a while, the same source should
put off like sort of smaller bursts. Which I think is why it matters that we have this,
this multi-sensor data confirmation, multi-sensor collaboration.
to be able to isolate a smaller point in the sky
because if we do find these rhythmic sources,
we can point these things, these other tools there,
for longer periods of time.
Exactly.
To try to potentially catch what is this.
It reminds me of the transient conversation we had the other day
where it's like there's this rhythmic pattern of the planet,
the exoplanet going in front of a star.
Yeah.
And so you have to monitor it for certain periods of time
to understand that it's not a one-off.
It's not a one-off.
Yeah.
And so what's interesting here is like what we're potentially seeing
with this specific really, really bright one.
may have been a one-off.
It may have been, I mean, we think it's a one-off because Chime was going around that same spot in the sky for the past like seven years.
It's had hundreds of hours in that region of the sky.
So we've only seen it once, right?
And it would have found even this even smaller radio bursts, but it hasn't.
And so it's like, what could be this one-off thing?
It could be, they're thinking it might be a magnetar, which is this, a magnetar is not a Pokemon.
No, sounds like one though.
A magnetar is sort of a newly born neutron star that's highly magnetized.
So it's got really powerful magnetic fields.
And it's in a sort of new stellar neighborhood that has magnetic material around it.
So it can create these fast radio bursts by sort of maybe it's like accumulating material and then it blows up or something.
Maybe it's accumulating material from the red giants that the James Webb Space Telescope saw.
James Webb saw some signal.
They just don't know.
It's like not good enough.
Right?
And because it's transient, it only happened for a little bit.
And then and then it's gone.
It's not like a star that I can just keep looking at and getting data, right?
It could be a magnetar.
It could also be a colliding neutron star.
But if it was colliding, you know, sort of revolving colliding neutron stars, we would have seen LIGO.
Yeah.
We would have seen gravitational waves, which we haven't in the hours preceding or since.
So maybe the collision is going to happen later,
and this is like maybe they're getting close
and doing some weird dance,
and then that released a giant fast radio burst.
But it's a new scale of astronomy, right?
Where before we had like only a few stations
that were relying on the Earth's rotation
to like maybe catch something, right?
And now we've got a dedicated sort of instrument
that is doing it on the Northern Hemisphere.
You can imagine we can create a global celestial
radio instrument that now does this.
Actually, the VLA also took a look at it.
Because now that we can locate it here,
the VLA took a look at it for several days afterwards,
trying to see if there's going to be a repeat.
Didn't see one.
The VLA being the very large array.
Yes, the very large array in New Mexico,
which is a giant interferometer of a bunch of radio dishes on train tracks.
For those who I think the movie was in contact with Jody Foster.
Written by Carl Sagan.
Written by Carl Sagan was at the very large array.
Yeah.
But again, this goes back to, I'm glad the outriggers were able to get out before funding.
Yeah.
This is why things like, you know, Chime, the Verra Rubin, which have this very specific use case of Sky Service that are not, that are just saying we're just going to get this.
Yeah.
This data set.
No.
Because we don't know where to look.
We don't know where to look.
We're just looking everywhere.
So we're going to create this map.
Yeah.
And then that'll help us know where to look.
Yeah.
And then everyone can write their proposals to then use these specific other tools to then look much more deeply.
Yeah.
And it's got to, I mean, fast radio bursts are only 20 years old.
You know, in terms of the grand scale of astronomy.
Right.
That's hundreds of years old science.
Yes.
Right?
Like only 20 years ago, we found the first one.
And these things are so ridiculously bright.
And it's like, what could possibly be making something that is as bright?
as a galaxy for a fraction of a second.
Right, right.
You know?
Don't get the Dyson sphere people in on this.
You're like, oh, obviously.
It's an alien civilization that's
harnessed the power of a planet.
And then when they recycle their
Generatron, it sends out this massive,
I'm being facetious.
Yeah, we should have an episode
about Freeman Dyson, though.
He's one of my favorite physicists.
Same.
He's one of my favorite physicists of all time.
I love, love, love Dyson.
Yeah.
Very clever.
Yeah.
Interesting.
Really funny, too.
Yeah, yeah.
Yeah.
Really funny guy.
Brightest fast radio bursts ever detected.
Yeah.
Because of some of the tools that we have, this is such a new area.
Such a new area.
And we haven't figured it all out yet.
No.
There are really interesting.
No, there are mysteries out there in the universe.
And we are doing good work to try to narrow the path towards discovery around some of these things.
Yeah.
And it's like, you know, when DeVera Rubin, I was listening to the,
the press conference for the Vera Rubin the other day.
And they were talking about,
they used Donald Rumsfeld's unknown unknowns.
Classic.
But it actually made sense here because, you know,
there are the known unknowns,
which is like what is causing the expansion of the universe,
what is dark energy, what is dark matter.
Yes.
What are these fast radio bursts?
Yes.
We know that they're there,
but they're unknown in what they are.
Right.
And then he said,
what I'm really excited about with the Verer Rube,
is the unknown unknowns.
Because before 2007, fast radio bursts were an unknown unknown, unknown, right?
Yeah.
People couldn't even imagine that something like this would exist.
Right.
Where in five milliseconds, it dumps like a ridiculous amount of energy.
Yes.
You know, that time scale for that amount of energy is insane.
And who knows how many, what number of unknown unknowns.
The Verirubin is going to find.
As we have these better tools.
Yeah.
And what the chime is going to find too.
Maybe it'll find like super fast radio bursts, you know, that are like,
Right. At the microsecond level.
Right. You never know.
You never know. We always cover a really fascinating array of stories each week.
We started with a deep dive on deep seek, no pun intended, and the geopolitical power war that is currently happening between the U.S. and China as leaders.
Europe, you know, eat your heart out.
You know, mistral is not really in the same category.
Yeah.
We went then to time crystals, the first time crystals that are room temperature and macroscopic.
That I can see.
That we can see out of University of Colorado Boulder, implications for any number of use cases, like security features, technology devices.
The third story was really fascinating about hidden viruses or DNA.
Could be big for medicine breakthroughs.
Yeah.
The fact that viruses are 8% of our DNA.
Of our DNA.
And there's these indicators that drive cancer and autoimmune diseases and understanding the structure, understanding the lock, now gives us the ability to build a key.
And then fast radio bursts.
Still an enduring mystery.
Yeah.
About where is all of this massive scale of light in such a short time scale.
What cosmological event could create something like this?
Yeah.
Something like that.
Another great week.
Again, the feedback.
We're still on the top charts on Apple for Science Podcasts.
Keep telling your friends.
Please keep sharing with your friends.
The comments are hilarious.
All you are comedians.
Some really, really funny comments.
I do talk.
I don't just sit here and nod my head.
Also, my hairline is not that crazy.
This is not Stephen A.
Smith.
And he's not the black guy from New Girl.
I'm not Lamarne Morris, although I appreciate.
Lamorin, if you want to have us on the LaMorneing podcast, we're literally down the street.
We'd love to talk to you about science.
My name is Lester Nare, joined as always by my co-host and our resident PhD, Krishna Chowdery.
This is from First Principles.
We'll see y'all next week.
Peace.
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