From the Vault: Horror Vacui, Part 3

University Press in two thousand and seven. Frank Close is a professor of physics at Oxford. I think emeritis now, but anyway, I was reading about this and he included a quote from the rig Veda that I thought was very interesting. This is from the creation Hymn of the rig Veda, which says, in translation, there was neither non existence nor existence. Then there was neither the realm of space nor the sky, which is beyond what stirred where?

And I really like this because it I think it encapsulates a kind of a fascinated but challenging history of attempts to conceptualize empty space, to even imagine what empty space would mean if it were to exist, Because I noticed kind of a gap here. As far as I can tell, most people all around the world today, even in various different cultures whatever, really, as far as I can tell, don't seem to express any major problems making

sense of the idea of empty space. Obviously, there is a lot we don't know about the nature of space. What is space, where does it come from? What different kinds of space could there be, and so forth. So space is still a vessel of many mysteries. It's not like we've got it all solved. But if you just simplify the idea to the basics, I and I think most people don't have any problem imagining the concept of an area of three dimensional space with no particles in it.

That just yeah, Okay, that makes sense as an idea to me. But if you read about how ancient Greek philosophers wrote about this question, I do not get the impression that the same was generally true for them. Not only did many of them deny the possibility of empty space existing, sometimes I get the feeling that they are struggling to even imagine what the concept would mean. Do you know what I'm getting at here, Rob.

to be linguistic possibilities in play. For example, I was looking into some sources on the void in Chinese philosophy, and you run into, for example, that they are separate terms for such concepts as emptiness, nothingness, and the infinite or the absolute and one source here, I was looking at Fan Magois in Frontiers of Philosophy in China from twenty ten, contents that their subtleties involved that quote English language is unable to capture. So yeah, we have to

acknowledge linguistic possibilities. But on the other hand, like thinking about like what is it as a modern human, Like, why do I, like, you have no problem imagining a vacuum or or even a void. And I think part of it may be like just the mechanical possibilities that

we have now and the media evidence thereof. So for instance, when I think about a perfect vacuum, I can imagine a device that mechanically makes it so within say a closed space, I can think back to footage of someone in a It's not a perfect vacuum, but a place that has no air, that's sort of vacuum. Because I

guess we get into differences too. Are we talking about a space without air in which say a scientist in a suit may drop a feather and a bowling ball and do that whole experiment, or are we talking about something that is a true vacuum with nothing in it

at all, like like an absolute void. And there are differences there, but yeah, as far as just like maybe it gets into the idea of imagining a space with air in it, Like we have this clear idea of what atmosphere is and what air is, and we can also see and behold and sort of to some degree understand the mechanics by which that air may be removed from a space, and therefore you could have a space where the visible is not present and the invisible has been removed as well.

idea was thought of before the modern era. So the pre Socratic Greek philosopher Thales of Militias, who lived from the seventh to the sixth century BCE, writing about the idea of emptiness or void without substance, is actually kind of tempted to ask can there be such a thing as nothing? If someone is able to think about it, wouldn't thinking about it mean it was something? And again this raises an interesting question for me. I mean, my initial reaction is just like, well, no, you know, so

imagine a container with empty space in it. I don't think by thinking about that we change the nature of what's in the container. But this does kind of raise the specter of like if there could be a vacuum for people like Thelees. Maybe this has almost more sort of totalizing cosmic implications, that the ability of a vacuum to exist says something about the universe as a whole, not just one region of the universe, say inside of a glass bottle or something. So that's one level in

which I respond. But then on the other hand, I can sympathize with thoughts like this knowing some things about modern physics, because in a very real sense, empty space is I think I can make the argument that it is not nothing. Empty space is something even though it

is not matter. So this may come from a failure to distinguish between space and a concept like nothingness, in which case, like if you're imagining space is something like space has properties, then in fact it couldn't be nothing, which is what Theyley's was thinking about.

you see this culmination of things in nothingness. Quote, nothingness is the nature of being in itself, which is absolutely transcendent and nameless. So if I'm interpreting this correctly, the sort of dual identity of nothingness in these two different thought systems, nothingness is ultimately that which comes before substance, but also comes before human attributed meaning. So yeah, like even thinking about even giving it a name changes the nothingness of it, at least from these perspectives.

According to Thales, it would be impossible for the universe to have come from nothingness, and it would be impossible for it to ever become nothing. There's just sort of like infinitely the same.

particles floating around out there. They're just very far apart compared to much closer to stars or in the atmosphere of a planet. But I guess the question would be how far apart does every individual particle of matter have to get before you say, okay, this is really a

total vacuum. But to come back to Theales for a second, close makes an interesting argument about Thales sort of having something in his cosmology similar to to a kind of empty space, basically a primeval material or a sort of ground state for the universe, and Close argues that for Theyales, this ground state of existence was water. This belief is related to the fact that we can observe water going through phase changes, so we can see water as solid ice,

as liquid, as water vapor. And Close says that Theales assumed that the diversity of forms went on from there, and in fact water was the basis of every material on Earth. Rocks, plants, air, et cetera. Are all somehow water in some extrapolated form, and so he writes, quote, space for Theales is as empty as it can be when all matter in it has been turned into its primeval form, liquid water, like the ocean. Water thus contains every possible form of matter.

It wasn't that everything came from water like they least thought that there was in fact earth, air, fire, and water. And Empedocles notably realized that air was itself a substance and not merely empty space. He also believed there was no such thing as empty space. But of course the discovery that air is not empty space does not mean that empty space cannot exist. But then we come to the atomists, who are very interesting in their departure from

these other ways of thinking. So the atomists included a number of ancient philosophers like Lucippus, Democritus, and Epicurus, who believed, quite remarkably ahead of their time, that all matter is actually made up of imperceptibly tiny particles, which they called atoms, from the Greek word atomos, which is derived from something that means like cannot be cut or basically indivisible. Now, of course, today we know that atoms are not actually indivisible.

They are made up of subatomic particles like protons, neutrons, electrons, and even protons and neutrons can be further subdivided, but ancient atomists did not have the experimental apparatus needed to discover this. Instead, they arrived at the atomic view of physics primarily by way of thought, experiments, and everyday empirical observations, such as the observation of things like the erosion of

solid matter in nature. So if you have a great, a grand marble staircase, and you notice that over the years, the steps on the staircase are eroding. They're sort of like sagging in the places where people walk on them. Well, they're solid marble. Where are they going? How do marble steps wear away over the ages? It must be because each person who steps on them removes some tiny, invisibly

small amount of matter. But that invisibly small amount of matter, those little atoms that are taken away accumulate over time and the steps are worn down. But importantly for this discussion, the atomists believed that there actually is such a thing as empty space. In fact, it was core to their theory that the universe was composed of atoms in motion.

Those atoms in motion needed a space through which to move, and the atomists argued that if there were already something in the place an atom was moving too, the atom couldn't move there because then two atoms would be occupying the same space at once. So there had to be such a thing as empty space. That was the only way that such space could come to be occupied. You know, there has to be space for things to move into

where nothing can move. But after this we get back to Aristotle, because we mentioned him at the beginning of the first episode in this series. For better or worse, Aristotle would pretty much have the last word on this question for centuries to come, until experiments in the seventeenth century would strongly challenge his decree. But Aristotle says there

is no such thing as empty space. And I was reading about the Aristotelian framework or foundation for the science of the early modern period in the Cambridge History of Science, volume three, edited by Lindberg at All. This was in a chapter called Physics and Foundations by the Princeton philosopher Daniel Garber, and he makes some interesting points. But reading this chapter, this is the way I was thinking about it.

So when we think of physics today, we usually of it as a science contained within certain boundaries, like there are certain kinds of questions that are physics questions, and there are other questions that are not physics. Is the study of properties of matter and energy something like that, and that's a huge field, so you can ask tons of questions in it, like how are stars formed? Or what is the relationship between particle mass and the Higgs field.

But if in a physics journal today you tried to submit a paper on a question like what are the basic modes of existence? And what is being? And what is the relationship of those things? To say, God, this would probably be rejected as outside the scope of the physical sciences, you know, like the editors would say, you need to submit this to a different journal. However, this attempted limitation of scope was not always present in fields

analogous to physics. Throughout history. There are many times in history where these things really kind of blend together, or at least philosophical foundations are thought to have relevant things to say about physics theories. So these philosophical foundations might

include religious worldviews. So you could think about the way that the scientists of the Islamic world in the Middle Ages might have thought of Islam as a theological foundation for the sciences or the way that Christian natural philosophers of Europe might have thought about Christianity in the same way. But in the West there was a major secular philosophical foundation of early science also, and that was Aristotelianism, the philosophy of Aristotle and a fourth century BCE Greek philosopher.

And I think it's fair to say that for like hundreds of years, in the schools and universities of medieval through early modern Europe, the philosophy of Aristotle was not taught in the way that it would be taught in

a college class today. Like today you would teach it like here is an interesting piece of intellectual history, maybe providing a certain point of view and showing the development of how people thought about X, Y or z. Instead, I think it was often taught in a way that was closer to how people would have thought about the Bible. It's like Aristotle said it. That pretty much settles it.

to believe in empty space. Garber, in his chapter quotes a translation of Aristotle for one of his arguments along these lines. Aristotle says, now it space or place has three dimensions length, breadth, depth, the dimensions by which all body is bounded. But the place cannot be body, for if it were, there would be two bodies in the same place. What in the world then, are we to suppose place to be? And the implied answer is nothing,

So not to kind of interesting contradiction. It seems to me at least that we had the atomists pointing to the fact that two objects can't be in the same place at the same time to prove that there must be empty space, because remember, moving particles have to have unoccupied space to move into. And here Aristotle is using the same premise in a way to say that space cannot exist independent of matter, or else it would have to occupy the same place as matter at the same time.

But coming back to close, he summarizes Aristotle's arguments by saying, quote, so for Aristotle, logics seem to require that empty space cannot be something and therefore is non existent. He defined the void as where there is no body, and since the basic elements of things exist eternally, there can be

no place that is completely empty. Aristotle may have been getting some mileage here out of confusion over the difference between empty space as something and like nothingness as in a way meaning non existence.

like there's sort of a law of nature something going on that will not let a vacuum be created, and thus forces matter to fill in the gaps. So you can pump out that container as much as you want, but horror vacue will prevent it from actually being empty inside.

And another interesting thing I wanted to flag here is that Garber notes a conflict between this Aristotelian dogma and some religious reasoning that arose in the Church in the thirteenth century that have led to the famous condemnations of twelve seventy seven, where we've got a bishop condemning Aristotle. So to read from Garber here quote one consequence was that without space outside of the finite world, not even God would seem to be able to move the universe

if he chose to do so. This apparent consequence of Aristotilian doctrine was rejected in the famous condemnation of Aristotle by Etienne Tempier, the Bishop of Paris, in twelve seventy seven, and then quoting in translation, here we condemned the proposition that God could not move the heavens with rectilinear motion, and the reason is that a vacuum would remain so Garber says, this really kind of put these scholastic Aristotilians in a bind, because in some ways they had to

defend the possibility of some kind of empty space existing in the universe, at least potentially for theological reasons, but they didn't want to vile the principles of Aristotle, to

which they were loyal. But anyway, going on, Frank Close makes an interesting argument that I think I would agree with that we shouldn't be too hard on the prevailing Aristotelian belief in horror vacae because without special equipment and experiments, I don't know, it really just seems like that from everyday existence, like it seems like reality prevents voids from forming.

Examples given by the ancient philosophers were things like, hey, you suck all the air out of an empty wine skin, the wine skin collapses like it shrinks in removing the air does not result in a void inside the skin. It causes the walls of the skin to shrink proportional to the amount of air you're able to remove. You could also use this belief in nature's hatred for the

vacuum to explain the workings of pumps and siphons. So beyond the fact that Aristotle said it, it just kind of seemed right with everyday experience.

sucks the liquid up. The same question was actually raised around the year sixteen hundred and brought to the attention of Galileo. There are some examples of read about this. One is an example of I think a scientist sort of at the time a natural philosopher who had been trying to construct a big siphon and encountered problems at

a certain height of the siphon. But then I've also read about an influence here being people digging wells and mine shafts who would try to remove water from these pits, using like plunger based pumps to lift the water out through a pipe. There was a problem in all these

cases with the siphons and the pumps. Basically, the pumps stopped working after a certain height after the water was raised roughly ten point three meters or so, when you had ten point three meters worth of a column in the pipe, it would stop going higher, wouldn't climb the pipe anymore, and instead a gap would appear between the water column and the plunger or the piston or whatever you're using to pump it out. So what's going on here was what was actually limiting the height of the

water pump system. Well, Galileo investigated this question, and he suspected that the force that drew water up through a pump or a siphon may in fact be the force of horror vacay. So the vacuum is resisting formation and thus pulling water up after itself. So when you try to run the pump, the fact that the universe is resisting creating a vacuum in that space in between is forcing water up.

Enter a couple of other figures. We got a guy named Gasparo Berti who lived sixteen hundred to sixteen forty three, and Evangelista Torricelli sixteen oh eight to sixteen forty seven. That rob I got a picture of Torricelli for you to look at here. I think he is incredibly notable for having a Batman symbol as a mustache.

liquid mercury. So Torricelli's experiment went like this. You would get a glass tube about one meter long and fill it completely with liquid mercury. So this tube would be closed completely at one end and open at the other. So you fill it with liquid mercury, and you temporarily plug up the open end, so one end is permanently closed. One end put a finger over it to close it, and then you flip the tube upright vertical and sit the open end down in a big basin of more

liquid mercury. So you got it like a tub of liquid mercury. So you flip it up. You have the the plugged open end facing down into the lake of mercury, and then you unplug it. You remove the finger the plug. Now, remember the tube started totally full of mercury, but now that it's unplugged, the mercury can flow down into the basin with the rest of the mercury. And when he tried this, the mercury in the tube did fall, but

not all the way. It fell to leave a column of mercury about seventy six centimeters in height, and then a gap for the rest of the tube length up at the closed top. So what was the gap, Well, Torricelli reasoned that it was actually a vacuum. There was effectively nothing inside the tube for those empty centimeters above

the column of mercury. The other guy, gasparo Berti, had performed a similar experiment with water several years before, and they both Both of these experiments seemed to provide evidence that it was indeed possible for empty space to exist, But the question remained, what was holding up the water in the tube, and why would the water only rise up the tube to a certain height, or, to put it in another way, why would the liquid only fall

down to a certain consistent height in the tube. The answer was also illuminated by Torricelli's experiment, for one thing, by comparing the difference between the height of a water column in a tube and the height of a mercury

column in a tube. They were different because water and mercury have different densities, and so what Torricelli proposed, and what in fact was correct, is that the force that kept the water or the mercury column raised in the tube was actually the force of atmospheric pressure, the pressure of the air pushing down on the water or the

mercury in the basin below. And these tube systems assembled by Birdie and Torricelli were actually systems for establishing an equilibrium between the weight of the liquid in this column in the tube and the weight the atmosphere exerts on the liquid in the basin below. The liquid in the sealed tube would fall until the weight of the column was equal to the atmospheric pressure, and then it would float and fall no more, leaving mostly a vacuum in

the space above. However, there was another question. There was the question of what is causing this. It was important to demonstrate that the vacuum was not the thing exerting the force. Tori Shelley did this with another experiment involving two mercury tubes, one with a sort of bulb on the sealed top end. And the bulb would mean that a greater volume of empty space was left at the top when the liquid fell after the bottom was unplugged.

So would that make the mercury fall to a different level. And it turns out the extra empty space did not matter at all. The liquid fell to the same height regardless. So the force exerted on the column of water in the pipe or the tube was not a pull from the vacuum. It was not a pull proportional to the amount of vacuum created. It was a push proportional to the relationship between the atmospheric pressure and the density of

the liquid. And this was further demonstrated in experiments performed by Blaze, Pascal and I think with some input from Descartes, but Blaize, Pascal and collaborators testing a similar experiment at different altitudes, so you might you test it at the foot of a mountain and then go up to the top of a mountain and test again and see if there are differences. And indeed they found that higher up on a mountain, the column of mercury would be lower

because the atmospheric pressure was lower. And in fact, these experiments and the apparatus used the apparatus what's the plural of that, apparati or apparatuses. Anyway, this stuff went on to become the basis of the invention known as the barometer, which is used to detect atmospheric pressure, and for much of history, one of the most common liquids used in it has been quicksilver or mercury. So people here in the seventeenth century had learned a number of things has weight.

The atmosphere does have weight, and it presses down and this affects all different kinds of fluid dynamics in closed containers, and at least in an approximate sense, vacuums can be created. But the scientific story does not stop there, and maybe in the next episode we can get into a little

more detail on that history, because there's plenty more. But also we've got to talk about psychology and horror vacae because I don't know about you, but you ever have that creepy feeling when you're reminded of like walking around at school when there was nobody there, or any other place when you were a kid that normally had people in it, but then there were no people in it and you were there and it just didn't feel right. I think about that all the time.

It's something that I feel, even as modern humans, we have to remind ourselves of this time and time again, because we can also fall into that line of thinking where we think of an empty room as empty, we think of a clear sky as being empty, but of course none of those things are empty. All of those things are completely filled up with air exerting a pressure on us, but a pressure that is so ambient that we do not register it as being pressure.

water is no longer sufficiently hot. Well, and of course it's boiling. You can't get any hotter than boiling, so you're just stuck like it won't cook.

lofty conversations of philosophers and scientists. Like the experience of boiling potatoes but not being able to cook them through that boiling Like that feels like the twilight zone. That feels like something that shouldn't be.

your mishaps with boiling potatoes and mountaintops. I know we have some mountaineers out there.