Cosmic Queries – Spontaneous Symmetry Breaking with Charles Liu

Information and entropy. Spice dust. All of that and more.

“Start Talk Special Edition Cosmic queries”

With our one and only geek and chief at the helm.

Charles, coming right up. Welcome to Start Talk. You're placing the universe where science and pop culture collide. Start Talk begins right now. This is Start Talk Special Edition.

We're doing a Cosmic queries grab bag. Normally, you see these over on our flagship Start Talk show. But we've got with us, not only of course Gary Riley Gary. Hey Neil. And of course Chuck Nice.

Hey. But the only way this becomes a party. When we bring in our geek and chief. Charles Lou, Charles, how you doing man? Hey, hey.

It is a pleasure to be here.

Thank you so much as always.

All right. All right. Charles is a professor of astronomy. Is that the department? What's the name of the department?

Charles. Department is physics and astronomy. Physics and astronomy. College of Staten Island. Covet Staten Island of the city university system of New York one time.

And many people don't know that Charles co-wrote the exhibit copy that lives in the growth center for earth and space. He was with us at the birth of the whole facility. So that was so much fun. We had a great time, didn't we, Neil?

It was all good. All good. And Gary former soccer pro. Yes. And I don't think Charles knows this.

Yeah. You're a new American citizen as of a few days ago. Hey. Yeah. All right.

I freshly minted. Welcome to the club, Gary. That's awesome. Thank you. The gentleman here are part of the reason why being in the US citizen for me is fantastic.

So thank you. Oh, wow. Okay. Thank you. Thank you. Now we have to live up to that.

No pressure. We're honored, sir. So we're going to find topics that really only Charles could give us the best answer on. That's what we put in the show. So let's get this party started.

All right.

Who's got the first question?

All right. I'll dive in first. And thank you to all our Patreon members for their questions and their curiosity. If we don't manage to get to your question this time around apologies. There's only so much time in the universe talking of which that's stopped.

Hannah Cantley from Oregon City and guess where that is. Yes. Oregon. I'm a big supporter and I love the show. So here's my question for Dr. Lou.

In a universe where gravity, matter and information all seem to emerge from the same underlying rules.

“And observers like us made of that exact same material, what does physics currently think observers are for?”

Our creatures like us just accidental by products of the laws or does the universe actually need observers in order to manifest or realize its own information? Oh, straight in the deep end. Here we go. What does it mean for the to be information anywhere? No, no, no.

No, this is actually a deep philosophical question right now. Yeah, in physics and the philosophy of physics. If a big bang happens in the multiverse and there's no one there to see it. Did it really happen? Right.

It's that kind of situation, right? Early on in quantum mechanics, right? There were people like Niels Bohr, the Copenhagen interpretation of quantum physics, which basically said that the universe is in a flux state of sort of unknown states in the quantum level until you observe it and then the wave function collapses is what they say and then reality appears, right? So in that kind of position, it is absolutely necessary for observers to observe something in order for wave function to collapse. Just real quick.

So it's called Copenhagen because Niels Bohr was Danish. Danish, A, B weren't the conferences there where a lot happened so that people associated these new thoughts with that country in that city. That's right. That's right. Okay.

So even to this day, yeah, Denmark. Even to this day is a hugely important part. They have a cosmology center there. Yeah. Lots of neat science going on.

Yeah. So the question then has since moved on and clearly even back then Niels Bohr wasn't saying that the universe didn't exist if they were no observers.

“It's just we didn't know what the universe consisted of until it got measured, right?”

But that has been taken to sort of its logical conclusion by saying that yes, actually observers are necessary and you'll find physicists today that stick to that point.

I remember also something that you did a long time ago, Neil and about reality in our brains, how the complexity in our neurons in the neural nets and so forth and consciousness and things like that.

Rivals the complexity on the large scale of the universe itself in the galaxies and the stars and things like that in the numbers. The total number connections in the brain and you look at the total number stars in the universe and they all interact with each other gravitationally. And so in our neural circuitry all interacts with all the rest of the neural circuitry. So it may be that the universe is less complex than the human brain. Right on the large scale.

And so if you take that into the next level. Before quantum physics was established, there was a philosopher named Rene de Cart, whom you've probably heard of.

“He's named, well, the Cartesian plane, the XY axes that you guys all did in algebra back in the day, right?”

What do you mean you guys? You did it too. What do you guys? Like you didn't do it too? It's true. Okay. Okay. What makes you think I actually showed up for algebra class? You're assuming facts that are not an evidence, sir.

Well, okay. This guy day cart basically said that reality is only conveyed to our brains through our senses.

So each of us actually lives within a reality that is distinct from every other reality that is visible. So in your brain chuck and in my brain and Neil's brain.

“Yeah. And he, I mean, honestly, that's demonstrable now.”

We actually have, you know, psychological experiments that have been conducted to show how we actually do live in our own distinct realities based on our experience and where we are and how we are receiving the information of the world itself. And one of those things that is most, I'll say, stark is how we remember things. Yeah. Events. We all remember events. So in a very distinct way. So go back to the point of observing. So correct me and you probably will have to, the dual-slid-slid-exper thank you, the dual-slid-experiment where particles go through and they look just singular.

And then all of a sudden they become waves, but as soon as you observe them, they go back to not wanting to be observed. So they become, right, single again. So how does that sit in with that explanation of observing? That's actually one of the big questions about that. The Youngst, the Tooslid experiment, which has now turned into a big part of explaining so-called wave particle duality. And one of the manifestations of this, if you're looking at it or trying to measure it with certain kinds of machines or detectors that are detecting waves, you'll find waves.

But if you measure it using something that detects particles, you'll find particles. And you can switch midstream and get a whole different thing that you expected originally just by how you choose to measure it.

And so it's a really amazing confluence between what's going on inside our heads, what's going on outside our heads, how much of it do we share, and how much of it is really truly only our own.

And I wish Hannah, I had an answer for you, but it is still being discussed. It is not yet confirmed whether or not observers are necessary for the universe to actually have an objective reality.

“You know, Charles, your account was so good, I think you should write a book on this.”

You mean, you mean this book? You wrote that really quick. You worked fast, brother. It was there, or it wasn't there until I observed it and all of a sudden, there it was. So, Charles, in that question, there's a direct reference to information and information like fields kind of intangible when you think about it.

Because I said it in earlier episode, you know, if I give you two oranges, you have two oranges. But if I give you two newspapers, you don't have twice the information, then you would have had one newspaper. So, information is clearly a different thing from what we think of as material reality. So, can you give us that quick primer on what a physicist means when information is the topic? Oh, it's kind of hard, but I'll do my best.

If you think about information as you're looking at a system with lots and lots of stuff, what is it about the stuff that distinguishes this stuff from other stuff?

Then you have another blob of matter.

“What makes this blob different from that blob?”

It's the information you get from it. Okay, it's not the form. It's not, for example, the whether it's an atom or whether it's a proton or it's a neutron. But rather whether it's spin up or spin down or whether it is this temperature or whether it is that. So, it's information in the way that we think about it.

Yes, but it also requires you to sort of think about it in systems of stuff. And not just the things themselves, but almost an abstract way of considering material. So, material can have information completely coursing through it. And unlike quantum physics, if no one's there to measure that information, the information is still there. Correct?

Yes.

It's kind of like an objective thing that's there no matter what.

But if you don't measure it, then you don't know what it is. An example might be a bit.

“You've heard of the term a bit in a computer, right?”

A 16-bit chip or something like that. The bit is the information one or zero or on or off. But it doesn't matter whether the bit is an electronic chip or whether it's a quantum bit, or whether it's a pair of electron positron or something like that. That information is still the important piece of the input or output that you're getting from that system.

Does that make sense? So, a lot of computation and thinking requires about the information that the physical thing is carry it and not the thing itself. This is can the nerd neck is a bearer from Michigan and I support StarTalk on Patreon. This is StarTalk radio with Neil DeGrasse Tyson. If you change the chemistry of something, you haven't lost any information,

because the information has changed, but yet the thing itself is no longer the thing. For instance, you set wood on fire. You end up with a charred remains and smoke at flames. The smoke is part of that information, but it's something else now. The flames are part of that information, but there's something else now.

The release of energy and heat and then what's left over is what's left over. That is no longer a piece of wood. Even if you didn't lose any information, the thing is no longer the thing.

“So, what is the importance of the information that?”

So, I think you just stepped on the big toe of entropy. Okay. Because entropy and information are closely linked closely. And you just stepped on its toe, because a log has much less entropy than a burned log. And so, Charles, can you walk us through that?

I sort of can walk us through, but it's long and complicated. But you hit your nail and head. The information has a lot to do with something. Okay, Gary, let's say you flip a coin. Yes, okay.

And it can be head or tail. Now, what happens if you flip 10 coins? What are the possible combinations of heads or tails? Well, one would imagine 50/50 if you if you toss them enough times. That's right.

Over if what if you tossed a hundred or a thousand or a million coins,

almost certainly you would wind up with 50% heads and 50% tails. Yeah. But there are actually a lot of different combinations. In fact, if you flip 10 coins, there are a thousand and 24 possible combinations. Point one is head, coin two is tail, coin three is head, coin four is tail, coin five is head, et cetera, et cetera, et cetera.

But the number of heads and number of tails at the end of your flipping, there are many fewer than a thousand 24. There's only 11, right? 0 and 10, 1 and 9, 2 and 8, et cetera, right? So, the out of the 1,024 flips that you can do.

There's only 11 actual results that come up with the numbers of heads and tails. All of that extra stuff, the other 1,013 rolls, are rolled into the entropy of that 10 coin flip. In other words, that stuff is the hidden information that will allow you to sort of come up with how often you're going to get five and five,

how often you're going to get four and six and so on and so on. So, entropy is hiding in there, the information you get off the top is hidden by that stuff inside.

the kinds of disorder that can hide in your systems,

“when you're actually just looking at the top of the system,”

finding out how many heads and how many tails there are. Do you like her? Yes. What did I do right? Please correct me if I wrong.

No, no, no, you said it, what you said it just fine, I just want to make it clear that Chuck was saying something different and I have to point that out. Okay, if you roll 10 coins and there's some chance that two will be heads and eight will be tails. Okay, that is not the total probabilities that Charles is talking about. Charles is talking about these particular two coins given you heads and those particular eight coins given you tails.

And if each coin is specific in that enumeration, then you get to the 1024. But if it's just two heads and eight tails and you don't care which two coins are given you the two tails, that's a different question asked of the 10 coins or of the hundred coins, whatever it is. Is all I'm saying.

Yes, Neil is precisely correct.

And so the stuff that's hidden that information underneath, right, that actual specific coin flips and then the actual result information that you want, how many heads, how many tails that difference could be said to be the entropy of the system that you don't see when you're getting the information out of the flips. So it depends how close you wish to look as to regards which data you get back. Yes, absolutely. This happens when we boil water, for example, when you're trying to turn water from liquid to gas on your stove.

What happens is that it stops at a hundred degrees Celsius, right, a standard boiling temperature for a period of time. And then the steam that comes off is still a hundred degrees Celsius, but it has so much more entropy, so many more possible states of the individual atoms moving around, compared with the liquid versions. It's not a matter of how far apart they are.

It's a matter of how much freedom, how far to move inside of it. That's right.

“And so in order to compensate for that, you have to heat the water up extra.”

You don't change the temperature, but you're changing the amount of energy inside because of the entropy increase that you have to put in in order to turn it into gas. In other words, the flame that was raising the water temperature gives the water to a hundred degrees and it stops raising the temperature. Where does that go? Where does that go and somewhere? Into the transformation.

Into the transformation. Into the transformation. Right, right. Excellent. All right.

Let's keep going. All right. Yeah, that was how you said it coming. It's freaking good. That's good stuff.

That was awesome. I look at it. Yeah. All right. This is Andrew Martin.

Hello, Dr. Tyson and Lou and the right Honorable Lord nice. Well, thanks, buddy. I'm right.

That's the first time I've ever been right and Honorable.

It says I'm Andrew from Stanford. Yes. And the English Midlands. Yes. We don't know what that means.

We don't know. We don't know what that means. It's a town in the West Midlands of England. Very pretty. Andy.

Yes. Well, it's so good if you just chime in from the staff. It's in the Midlands. The shyness. It's the shyness.

It's the shyness. Indeed. I believe that's somewhere near. They make good whiskey there. No.

Well, they make they may do, but it's not known for whiskey. No, right. Is it anywhere near down to the abbey? Because. Okay.

Okay. Here we go. Here we go. He says, anyway, I understand that a star's color is determined by its age and composition. I also know that it's velocity relative to our collective selves can redshift its light.

How do you resolve between the two?

“In other words, how do you know a star is made of something and traveling at a certain velocity?”

Isn't really made of something else and traveling at a different velocity? Man, we've got people say the curve of the edge deep about the man. They really have a superb question. And in fact, I will say that that is actually a problem for astronomers sometimes. We don't know whether or not the objects colors are caused by or the redshift of emotion as opposed to the redshift

of the expansion of the universe or the colors intrinsic to the objects themselves. The answer to this quadri is spectroscopy.

So instead of just seeing red, you see very red, an orangeish red, orangeish orangeish red, orangeish orangeish red and so on.

Until you finally get to the most orange of all.

Okay, yes, until you get to that orange. But what happens is that by dividing all these colors up into little bits, the components of that reddishness that you see from a star are broken up into emission lines, absorption lines and continuum radiation. And the patterns of those different lines and continuum are preserved regardless of whether or not you redshift due to velocity or not. So if something looks red, which you thought was blue, you measure the object using spectroscopy and you take a look to see if the patterns absorption and emission lines have been preserved in the red part of the spectrum when you thought it should be in the blue.

If they're preserved, then we know it was because of redshift. If they're not preserved, then we think, oh, there's something physical going on in the star that made that color change. You know what else happens? A star can sit behind an absorptive gas cloud, a cloud with dust in it. And it could shift a white star, the color that you'd see for a white star into a regime that makes it look red.

“Big, big challenge for us. Do we really know what's in our site line that could be messing with the star itself?”

So what you're saying is you're looking through this dust cloud. Yes.

At the star, but you don't know it's basically you don't know it.

It's like a little screen. You try to understand the dust cloud and sometimes you forget that they're there. And Charles, wasn't there a huge discovery made about the big bang, and because they didn't correct for the for the reddening in our own galaxy of the cosmic microwave background. But there was some paper that had to be retracted because they, you know, retracted not because it was fraudulent.

It was just they had to say, we messed up and we're all. Yes, that's right. Yeah, yes, because the cosmic microwave background, as it currently exists today,

“produces the same wavelength of microwave radiation as dust of a certain composition temperature.”

Okay. So that dust turns out to envelop our Milky Way galaxy. It different thicknesses or different densities depending on which direction you look. And so if you were unable to get that signal cleared away from the cosmic microwave background, that interference will completely mess up your interpretation.

I was going to say it's like the tear function on a on a scale. Yes. You know what I'm saying? Excellent point. That's what it is.

Very good. Yes. So being able to see that. How do we, I make it go away? And if it's not possible, how do we navigate through this sort of natural filter that's there?

Neil, do you want to tell them about extinction curves or do you want me to do it? So we got you on here, you're geek and chief. I'm just a geek and deputy. It's a great question, Gary, and it's actually pretty complicated. But I'll try to make it as simple as possible.

Essentially, the effect of dust in making things look dimmer and redder is known in astronomy as extinction. Okay, not the kind where like dinosaurs go away because they're hit by an earth is hit by an asteroid. Right. But the kind of extinction that says that your light has been extinct or extinguished because of this dust.

“What you have to do is A actually understand what dust does.”

And so there's a whole branch of astrophysics that is done in a laboratory where you make dust. That might approximate what interstellar dust is looks like is made of what shape things like that. And then you shine light through it. And then you see what that dust does to the light that you might expect coming from a star or something like that.

And then the second thing you do is you have to measure where dust is throughout your lines of sight from earth out into deep space.

See how much dust and what kind is in that line of sight and everything you see in that direction has to be corrected. For this extinction. And so there's something called an extinction curve. Okay. And every kind of dust has a different extinction curve.

So you look in a direction say I look at a galaxy that's in that direction far away. I first have to ask okay, what does the galaxy's light look like from my telescope and the second thing is I have to ask somebody who did measurements of extinction.

And then that person will say oh that line of sight was measured to have this much extinction and these kinds of gases and dust.

“And then you go okay and then you make a correction to make your galaxy light what it would have looked like had the dust not been there.”

Oh my god. It's a complicated. That's the same. So the universe is not just sitting there waiting to be discovered. We have to figure this stuff out.

Yeah. That just sounds awful. Although it sounds awful in one way. Yes, it makes our ability to understand those distant galaxies that much tougher. It's also a blessing in disguise because it allows us to understand dust in the universe.

Okay. If we want to know what we humans are created out of literally, start us stuff that came off of stars cooked in the hearts of stars and then viewed out into the universe in the Milky Way galaxy. So if we want to know where we came from as human beings or as life forms or even as planets. Right.

We need to understand that dust. So the combination of being forced to be able to compensate for that dust and to be able to know it's behind that dust has given us the opportunity to study the dust itself. Which I think is pretty awesome. That is pretty awesome. But I will also say when you were talking about the discovery of the that the paper had to be retracted.

And first I was just like god, man.

You know, these guys really screwed up. Now I'm like, yeah, I'm on their side. Like, you know, basically, I'm surprised everybody's able to find anything. That's right. Basically, every after the week a paper should come back. My bad.

It was dust. It was dust guys. Sorry. There's another feature that there are. I would call them ambulance chasing theorists who saw these results.

I can explain that with a new model of the big bang and that there were people who published papers on these false results. Oh, so yes. So that's an important reality check on the front of the moving front here. But that's what we do in science. Charles, this sounds like an awful lot of man hours to log chart.

Oh, yes. Tablet all of this information surely. This is perfect for AI. Yes. People spent entire careers doing these kinds of maps. I'm sure Neil, you'll remember, uh, Schlagel did a lot of this. Bruce Drain did a lot of this.

Some of the giants of our field are remembered for their legacy of making these maps happen.

“The problem with using an AI to try to make those maps is that you have to have the AI.”

Interpre it just as the question was saying, how do you tell the difference between what dust is causing and what the light is causing from behind it. AI isn't sophisticated enough to tell that difference yet. It just sort of chooses the best option and sticks it in. So there's that human need to be able to disentangle these two effects, which something like a large language model still not quite able to do. Uh, so AI eventually will be extremely helpful in refining maps that we had found a long time ago and used optimal methods to figure out what they were.

But they will be able to make maps on their own because they don't have the decision making capability yet. The distinguish between the different things that are causing what we think dust might be causing. Okay. Well, at least that's my opinion. And you're sticking to it. Hi, bring it on. We got to know it.

We ready for the next one. Okay, April. Hello, sir. Neil, Lord Chuck, and Sir Charles, I'm April Wash. Yes, and you're right, April.

This is an easy one to pronounce. My 16 year old son and I are obsessed with style talk well done. We absolutely love it and thank you for making it great. My question is, when all of the matter, here we go again, dust, gas, etc. In the universe was condensed into something smaller than a pinhead at the Big Bang.

How did that not immediately create a black hole? Interesting. Wonderful question.

“What does that question get out of that one, Charles?”

It turns out that we don't have to get out of that one because the universe got out of that one for us. When the universe was the pinhead sized, it actually wasn't that massive. We think of the Big Bang or think about the Big Bang as rolling back the history of the universe and making it smaller and smaller and smaller.

But at the moment of the Big Bang, the mass of the universe was, well, at 10 to the minus 43 second after the Big Bang.

The Big Bang, what we'll call that, the Plunk Time. The mass of the universe was less than a glass of water.

Something further happened to inject the universe was so much energy that that inflation happened that you probably have heard of,

where at the nearly the beginning universe, you wind it inflating the universe beyond its regular expansion rate by factors of many, many trillions. And then you wind up with all this extra energy in there which then condenses into matter and becomes the galaxies and stars and planets and black holes that we have today. So there was a period of time early on where black holes didn't even do. We're that energy come from. Where that energy come from is still a hundred percent unclear.

I don't know. But there are some guesses. We know where it came from.

Came from Jesus.

“Came from Jesus. That's part of the problem, right?”

A lot of people do, in fact, have a problem with that Big Bang cosmology at that early time because there seems to be no way for us to explain that injection of energy anyway other than some sort of divine supernatural activity. But if we were to do that, then we'd just be like, "Oh, okay. We've given up on science. We're not going to try to figure out how it actually works. Let's just go home and have a drink and forget about."

So we refuse to sort of give up and just say, "Oh, it was something that will never be able to understand. It was some divinity or was some supernatural thing."

So if we try to think about nature, then the way you can actually inject energy has to do with something called spontaneous symmetry breaking.

“Neil, have you told our distinguished patrons about the fundamental forces in the universe?”

Yes, you know. Yeah, yeah, okay. So we know currently we think that the universe has four forces in it that sort of determine all of the transfer of energy and material and so forth around the universe. There's something called the strong nuclear force, the weak nuclear force, the electromagnetic force and gravity. Okay. Now, gravity is its own strange beast because there is a hypothesis that gravity is as a force actually has more to do with the structure of space time than the transfer of little particles back and forth.

But electromagnetism, the strong nuclear force and the weak nuclear force are now separate forces. They have different mathematical explanations and they behave differently depending on where they are and what size and scales and so forth or around. It makes sense to hypothesize that right around the time of the big bang, there were not four forces, but there was only one. And something happened at the quantum level to break forces off from one another and that break is called a spontaneous symmetry break.

So when I was saying spontaneous symmetry breaking, you can imagine something breaking and from the inside of that break that used to be symmetric. There's one beautiful force that followed all of its math now is two or now is three or now is four. And the resulting chaos, it's almost like unleashing to some extent that entropy we were talking about we're trying to boil water, but now we're unleashing just straight up energy in such huge densities and such huge amounts that it propelled the universe to grow at such a rate and such a speed that we pass the black hole thresholds and then you have to start all over again and turn that energy into matter and then make black holes.

Wow, that's pretty well. Okay, so how do you feel about we didn't have one to show, but we were supposed to.

“I believe her name is Sabine Hoffman something she's.”

I mean, I don't know, but you guys know who I'm talking about. Okay, so now she says that anything anyone who tries to survive what happened at the Big Bang is only telling a story because we don't have and we never will have data that will allow us to make a conclusion. How do you feel about that? Well, that's a great philosophical point of view. I would answer all of physics, all of astronomy is trying to tell a story, right? The hypotheses of every explanation as to why something happens in our universe is a story.

And so we're always pushing in that direction. If you could tell a story that can be falsified, but can be shown to be untrue based on observations or experiments or something like that, then you are trying to do science. We have for ever thought that, oh, we would never be able to see like the origins of our earth. And yet here we are able to understand planets because we kept asking questions and finding ways to look further and further back in history. We used to think we could never understand how our solar system was formed. It must have been supernatural must have been divine, but no, now we know because we looked and we found ways to find a hypotheses that we could test.

So we are going further and further back. How can we find the formation of galaxies? How can we find the birth of black holes? And now to the point of the big bang itself.

The recent results from the Dezi group, dark energy survey group are remarkable. They are looking at echoes of the imprints of matter and energy in the large scale structure of our current universe that were put in there. Very close to the big bang. Before even the cosmic microwave background was established. We are talking about like ripples in a pond that have been imprinted in the galaxy distributions of our universe for the past 13 and almost 14 billion years. And we are seeing that imprint which itself is long past the beginning of the universe, but maybe that's fossilized information that could tell us about things like the big bang which we just can't see anymore.

“So it's a philosophical point. That's what science is so cool about. And you have to watch out to presume that just because we have ideas about something that it'll never be tested.”

So it's a philosopher in the 19th century was, I'd love this paraphrasing. I'd love this field astronomy. We can know where the stars are. We can know what colors they are, but we will never know what they're made of. We have to go there. This is like 10 minutes before spectra as applied to astronomy was invented and with spectra as Charles said earlier, you can find out what are the chemical components of stars as one of the great triumphs of 19th and 20th century modern astrophysics, but the fact that we didn't know and someone got clever and figured out how to know.

We've never stopped on the frontier just because we don't know how to do something yet. That we'd still be in the caves if that's how we function to scientists.

And that's why I always tell everybody that the questions are more important than the answers because we can't get all the answers now, but if we ask the right questions, someday we will be able to answer them. The German poet of Rainer Maria Rilky in his book, "Letters to a Young poet." I hope I don't mangled this too badly to one of the poems and be patient with all that stirs within your heart. Learn to love the questions themselves.

“See, that's what I tell my wife when she's like, "Where were you last night? I'm like, "You need to learn to love your questions."”

The answer is not really the whole issue here.

That won't for you. Not probably, but what we're dealing with here is no non-nones rather than non-unknowable balls. So to try and get ourselves into the position where we do know, different thinking again, because we've used our own thinking that we've brought historically. So it's not quite the change of angle of approach, but a different way of thinking about the same conundrum subject. Yes.

“How do we go about altering our thinking as to provide us with an answer for this?”

Well, the history of science is not linear nor is it continuous. Right? What we found over the centuries is that people ask a question and they can't answer it. And then you wait a, sometimes a really long time, and then somebody just goes, "Hey, how about this?"

And then somebody else says, "You know what? We probably could. I'm thinking, of course, of general relativity." Right?

“Neil, you know that famous story. People are trying to figure out gravity forever and how the, how light travels through the universe.”

And then over about a 15-year period, Albert Einstein first defieses the special theory of relativity and then the general theory of relativity.

And people like, "Oh, space bends and curves." That's very interesting, Albert, but how we ever going to figure that out. And a guy named Arthur Eddington says, "I know how we can figure this out." And organizes an expedition to see a total solar eclipse and take photographs. And sure enough, he was able to measure with his colleagues that very amount of curvature and space type that Einstein had predicted. And so people had been thinking about gravity ever since Newton's time, and then within that short 10-15-year period, boom, we figured it out.

But then we had to wait another long period of time to the next thing, and the next thing. Just to clarify, the eclipse itself is not what Eddington looked at. He needed the eclipse to darken the sky to see starlight from far away in the universe. It's path moving to the side of the sun. The sun is the most massive thing we have available to us. So if gravity is going to distort the fabric of space and time, the sun is our best chance of this. So he waits perfectly. - Perfect set, Neil. - Yeah. And then the starlight comes across very near the edge of the sun.

He measures where it is on a very with great accuracy. Then waits six months to the sun is on the other side of the sky, goes back to that same area and measures where the stars are on his frame. And they had all moved in the presence of the sun, having their path length, go by the limb of the sun, relative to six months ago. So that whole project took six months to confirm. And there was an eclipse in 1918 that he really wanted to use, but the world was still at war.

And so that was a lost opportunity. It was delayed until 2019. - Right. - Right.

“Now, yeah, you're completely right, Neil, and what you've said, the key there, Gary, to sort of circle back to your point, wasn't the eclipse,”

but it was to use the eclipse as a way to measure the curvature of space and time, and thus the motions that are different. - And then going back in six months, you've got a constant, because the stars will be the constant and you're working on it. - I get that spoon. - Thank you for that. So when he looked at the light from behind the sun, then the movement was meant that the light had to bend in order for him to see it the way he saw it. - Correct. - Gary. - That's it. - And then he only did it, but it done that would have been the actual mass of the sun, because the sun is so massive.

- And the way to affirm that is wait six months now, the sun is on the other side of the sky. - Go back. - Go back. - Well, that is, first of all, I... - In the case, it's rice. - It's just smart people, he's just smart people.

- I mean, here's what's in it, but it's so simple, but it's so brilliant.

- I feel so dumb. - What was that boy so dumb? - No, Chuck, I feel like that all the time, it really is amazing how smart all of our lives are. All of our predecessors have been, yeah. - And we live in a time when people say, "I'm just scientists, what a scientist." - No, I'm just... - Now I'll figure it out.

- Yeah. - Yeah. - What do you think we do? - It's the all we do, we try to figure stuff out.

- So Charles, that information was always there.

- Yeah. - It didn't just appear, because Eddington showed up with some calipers and measuring stuff.

“So it's looking at things and thinking, what information is here?”

- We are not thinking or seeing or identifying. - Gary, one of the prevailing and persistent definitions of genius is the genius is the person who sees what everyone else sees, but thinks the way no one else has thought. - Wow. - That's pretty cool. - It's not just looking at seeing. - Okay. I'm not a look-see guy, you know, to me they're the same thing, but that's fine.

- Oh no, you can look at things, but you won't see what is really there. - No, no, but that's like saying, you heard me, but were you listening to me? - Yeah. - I'm not, I'm not a heard-listen-see, I'm not that guy.

I'm just, you know, as this discussion opens up, it makes me think,

“is that information we need there? We just don't quite know how to extract it right now.”

- In many cases, yes. One of my colleagues right now is doing an amazing, a kind of theoretical work about quantum information.

When you're trying to send information through, say, fiber optics or something like that, you lose information because there's noise in the system. But this guy is like saying, you know what? I can take that noise and learn, find information in there that we thought was lost, and thus make my quantum communications that much better. It's amazing. It's like thinking about dust in the solar system and the galaxy blocking our view of things we want to see, but then turning around and saying, you know what? That dust itself has information.

“I wonder what we can learn from that. It's that kind of thing that happens on every scale.”

- We're not talking about acoustic noise. We're talking about light noise. We have a light signal going through fiber optics. And so noise is in physics is a general term for interference of a signal that would interfere with the target signal. It's not just acoustic. It can be an interference background, static, all that stuff. Imagine if you could figure out stuff and that, you know, that just changes your whole dynamic of what you're trying to be able to transfer. - The original discovery of the cosmic microwave background using horn and horn, yes.

- Jersey, they said, you know, they're working for AT&T, the labs and AT&T said, let's find out what the noise is in the background so that when we send signals through the air, we will be able to understand that noise and possibly correct for it. Okay. So they open up their antennas and they look in every direction. And there's this residual noise everywhere they looked. And they said, okay, we're going to have to report this, but wait a minute. Let's look inside the antenna. They look inside the antenna. There was pigeon-dong in the antenna. It's reported as a dielectric substance.

And they're never going to survive. Which actually can be responsible for a noise level. So they cleaned out the pigeon poop in this antenna.

- Good job. - And then they went back and had dropped the noise level, but it didn't take it to zero. And so they reported excess noise every direction in the universe, and that was the cosmic microwave background. No bell prize winning discovery after they removed the pigeon poop. - Now first of all, a pigeon, a pigeon should have got the Nobel Prize. - God, this shit should have got an assist. - Okay, assist. - What the pigeon's a stock hole. - Here is the dielectric substance that help us find the cosmic microwave background.

[Music] - Okay, let's see if we fit in some more questions here. - All right, you're a very luxurious character. - Okay, let's see if we fit in some more questions here. - You're a very luxurious character. - Okay, let's see if we fit in some more questions here. - All right, you're a very luxurious character. - Okay, let's see if we fit in some more questions here.

From Kalamazoo here with observatories like Webb and Vera Rubin already pushing the limits of what's technologically possible.

“What scientific and engineering breakthroughs do you think the next generation of telescopes will demand?”

And what new discoveries might those future inventions unlock? - That's not going to be a quick answer. Can we just pick like one thing? - Let's go. - Go pick one, I'll pick one, I'll pick one. - All right.

- But that's a tremendous question, wonderful. Okay, the one breakthrough I think is going to be amazing is the ability to fly spaceships in formation.

When you fly spacecraft that are basically going in lockstep with one another, not deviating by even a millimeter over thousands or millions of miles of travel, then you can use something called laser interferometry and shine and position the light and the detectors in such a way that we can find gravitational waves from space at level that's hundreds or thousands of times greater than we can all the ground. - So you're saying that these spaceships become an array, is that what you're talking about? - That's exactly what we're talking about. And so that technological development is just the one that I'm going to mention this time around.

And that's going to be able to let us map the universe like a well-struck gong, I think it's just amazing. - Wow, wow. - That's good.

“And I'm looking forward to more telescopes that operate that are sensitive to things other than light, because we've got the whole spectrum mapped out.”

All right, we've got, and gravitational waves is another version of telescopes that operate outside of light is using gravitational waves, but they're looking for neutrale telescopes. There might be some other particles that dark matter telescopes, things that will see the universe in whole, not just different windows, but whole other buildings in another windows in another building for what is otherwise is going on out there in the universe.

And this could be a new frontier opens up much the same way when we discover this more than just visible light coming to us in the universe.

Let's build a telescope to see in it. Oh my God. All right, our eyes were so feeble compared to what the universe is trying to tell us. And right now we got the whole light spectrum figured out it's time for new frontiers in cosmic discovery. - In NASA speak, we call that multi messenger astronomy. Oh, which of messenger is not just light waves, or electromagnetic radiation of any kind. - Didn't know they had certain particles and exotic things. Yeah, multi messenger astronomy. Watch very cool. - Oh, and by the way, Galileo's famous book from 1609, we're reported on his telescope observations of the universe, something no one had done before.

The title of that book is "Sidearius Nutsius", translated from the Latin starry messenger. The stars were the messengers. - Hmm, okay, awesome, go for it. - Next one, right, we do that in like, for a minute. - I know, okay, right, you guys should joke.

“Hello, Dr. Tyson Lew and Lord Nye, shall get some India, the handy quantum physics answer book actually created a lot of questions in my mind, then it answered. - Oh wait, which book now, yeah?”

- Which we did this guest ask about? - I'll say it, Slovak. - The handy quantum physics answer book. - And what's handy about it? - Oh, you mean, you mean, that's handy quantum physics answer book. - That one. - Listen, everybody, I'm sorry, that was a pretty self-serving, but I'm really proud of the book. It really is a great opportunity. - So are we, is he a proud of the book? - Well, we are proud of you. - Oh, so, so kind, thank you. Here we go, thank you. - Okay, please continue, please continue.

“- Does the Sean Horses' effects imply that the universal speed limit is an environmental variable rather than a fundamental constant?”

If so, could an advanced civilization pump the vacuum to create local bubbles of infinite causality and would this effectively turn the universe into a lossless energy distribution network?

- Oh, it's all yours. - Amazing. - It's a chance you take this one.

- It's a chance you take this one. - It's awesome. - I haven't heard about the Sean Horses' effect being asked in a very long time. A scientist named Sean Horses, I think it was around 1990 or so, hypothesized that if you took two perfectly smooth metal plates and brought them within a millimeter or a millionth of a millimeter within one another, you would create a zones because of the quantum fluctuations of the universe where the index of refraction was less than one. What it means practically means is that in those tiny zones that are only a fraction of an inch across, the speed of light could actually exceed the speed of light in vacuum.

This would be a hypothetical, there's been no way to be able to test it and the effect is tiny. So it would be one trillionth of a trillionth of a trillionth of a percent faster than the speed of light in vacuum across this zone, which was less than a millionth of an inch across. So it's this really neat effect that if we could test it, it would be neat to find. Unfortunately, we cannot create, at least as far as we know, if the Sean Horses' effect is true. These kinds of pumped spaces that our questioner is asking because the causality and the speed of light and the stuff like that at those micro levels cannot translate into a macro level thing like being able to draw energy from nothing.

Now that said, and I'll just stop with the technical mumbo jumbo in one sentence, the concept of zero point energy, which is what the Sean Horses' effect is talking about, is still highly uncertain.

Charles, is this related at all to the Kazimier effect? We need to have two parallel points within evacuated space between, but this is taking it up another level, is that?

Correct. We have a cosmological phenomenon inside. That's right.

“Quantum cosmological phenomenon rather than just a sort of a laboratory thing. I mean, is that?”

Yes, that's right. The Kazimier effect is exactly what we're talking about here. Kazimier, everyone in case you don't know, C-A-S-I-M-I-R. That's right. The scientist, Dr. Kazimier hypothesized it exist and it was in fact measured to exist, that if you bring two plates of metal really, really close together, you actually wind up with energy that sort of magically, but not magically. Yes, that's right.

And so this is taking it to the next level, the Sean Horst effect would be like. The two plates are attracted to each other by forces that are not gravity or electromagnetic. That's quantum. That's quantum. That's insane.

I love it.

All right, next one. What's going to get more more in here?

Great question. Here we go. This is Naravshah, who says hello, astro-gentlement, Naravshah from Arizona. My question is, can you point me towards some resources where I can learn more about the universe, theoretically and practically, as an ardent receiver of Starlight, knowledge from StarTalk, I often paint an incoherent picture of the universe. I want to learn more, so I can ask better questions. I've got a book for you, man. It's called the quantum hit, the handy.

[laughter] It sounds like he's not in a hurry, so my book AstroPhysics for people in a hurry, that's not for him, because he sounds like he's got to learn on his hands. Sure, how many pages is your book? Geez, I don't know, let's see. I'm looking at each of these.

Yeah, yeah, it's like four hundred and fifty-eight pages. Yeah, yeah. That's a commitment. Yeah. Yeah, but not really, because you got to understand Chuck's book is broken up, so that it's almost like a resource.

You don't have to read it straight through. Yeah. You can read about the scientists of quantum physics in certain parts. You can read like from the beginning, which is very good.

“The very beginning of the book is great for just like, what is a particle?”

What is quantum? So, you know, even though it's almost 500 pages, don't look at it like it's 500 pages. It's broken up in ways that you can digest it in chunks. So it's really resource is a good word for it. Yeah, it's a resource.

Yeah, you're very kind to say that. Yeah, and then your description is exactly right, Chuck. I wrote that book specifically to say, "Hey, you could take it in whatever size pieces you want." And whatever level you want to go at it. Chuck was not being kind, he was being factual.

Don't confuse the two. Now if you're not. If you're not. If you're not. And he said, "You were a nice book. Then he's being kind."

You're very kind. Thank you very much.

“No, I would say if you want to go deeper into the mathematics,”

because the handy quantum physics answer book and many of the other books that about these topics are usually talking about deep concepts and ideas. But those ideas arose from the mathematical and the scientific depths of really trying to wrestle with the equations that describe how the universe works or the calculations or the measurements that would give us a clue about how the universe works. So if you want, I'll just mention this. There is a group called OpenStacks, STAX. And it is free for anyone who wishes.

It's basically a set of textbooks. These are textbooks that are legitimately for people who want to learn or to major in something or to do. But it's free on the internet. And I encourage anybody who wants to look at some of those things to see, like, get a little taste of what an actual textbook looks like. And see if you want to go deeper into it.

See if you want to drink deeply of that stygian spring. Or if you would rather just have a little knowledge, which, of course, is Alexander Pope says, is a dangerous thing.

And always remember, a mind is a terrible thing.

That's the bad part. Sorry, sorry.

Yeah, there's a lot of good stuff now.

I encourage everyone to take a look. I think that's all the time we have. Well, you can chief.

“We love you, but our fans love you even more.”

I'm, I'm very, very happy to be with you guys always.

Gary Chuck. Thank you. It's so much fun for me. And I really, really appreciate. Glad you do.

Chuck, good to have you, man. Always the pleasure. All right, Gary. Thank you, Neil. And thank you, Charles.

Start talk, special edition. Cosmic queries.

“And it's been a geek and chief grab bag.”

All right, guys. Good to have you. Neil, the grass Tyson.

As always, being in you, take care.