The Joy of Why - Will Better Superconductors Transform the World?
Episode Date: May 9, 2024If superconductors — materials that conduct electricity without any resistance — worked at temperatures and pressures close to what we would consider normal, they would be world-changing.... They could dramatically amplify power grids, levitate high-speed trains and enable more affordable medical technologies. For more than a century, physicists have tinkered with different compounds and environmental conditions in pursuit of this elusive property, but while success has sometimes been claimed, the reports were always debunked or withdrawn. What makes this challenge so tricky? In this episode, Siddharth Shanker Saxena, a condensed-matter physicist at the University of Cambridge, gives co-host Janna Levin the details about why high-temperature superconductors remain so stubbornly out of reach.
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On April 8, 1911, a Dutch scientist made a chilling discovery.
Using a carefully engineered instrument filled with liquid helium,
physicist Heike Kamerlijn-Ones delicately lowered the temperature of mercury closer and closer to absolute zero.
mercury closer and closer to absolute zero. Suddenly, at an unimaginably cold negative 452 Fahrenheit, the supercooled mercury conducted electricity with perfect efficiency and no energy
lost to heat. It was the first superconductor. I'm Jan Eleven, and this is The Joy of Why, a podcast from Quantum Magazine,
where I take turns with my co-host, Steve Strogatz, exploring the biggest questions
in math and science today. The discovery of superconductivity would win Kamerlingh Onnes
the 1913 Nobel Prize in Physics.
But more importantly, it marked the start of an unresolved quest for material that maintains
perfect conductivity at room temperature, a quest that's recently seen many claims put forward
and then retracted. Today we ask physicist Siddharth Shankar Saxena, known to his friends as Montu,
what makes room temperature superconductivity so elusive, and how might its discovery reshape
society? Montu is a principal research associate in the Cavendish Laboratory at the University of
Cambridge, researching superconductors, magnets, graphite, and renewable energy applications.
He also teaches at Cambridge's Center for Development Studies and chairs the Cambridge Central Asia Forum.
Welcome to the show, Montu.
Thank you, Jana. Excellent intro.
Thank you.
And I think a very fitting thing to say, chilling discovery.
Yes. Our script writers like puns.
Before we get into the absolutely amazing and unforeseen phenomena of superconductivity,
I want to talk about regular conductivity.
We have fundamental elements just on our periodic table, things that are made in the universe
that are conductors, and we call
them metals. Can you tell us just very briefly the basics of conductivity?
Sure. So there are different ways of understanding conductivity, conductivity of water,
conductivity of heat, conductivity of electricity. And these properties of elements is one side
commonplace and another side extremely mystical. Like when you walk into
a room, you flick a switch and something happens. We can say a circuit is completed, the current
starts to flow. It can only flow in a conductor. It's a conduit through which things can flow.
And if it's not, it stops flow. It's an insulator. So you flick that switch and you
allow the electrons to flow all the way to your light bulb, your computer, your fan,
or whatever else that is, and it starts to work. And that is conductivity. And the material
property needed for that to happen is metallicity. Something has to be metallic for it to
have basic conducting properties. Of
course, there are various caveats, and that hopefully we'll chat about as we go forward.
Yeah. So basically, these elements in the periodic table are all lined up on one side
because they allow their electrons to do what you're describing, to run freely through the
material carrying energy with them. And insulators hang on to their electrons and don't allow it to happen. I use a cloth to hold my kitchen pan. But the pan itself,
I rely on allowing the conductivity. Now, how is superconductivity so much different from this
naturally occurring phenomenon? First of all, we often think electrons can freely move in a
conductor, but they don't really move freely.
That is the reason why you have your electricity bill. When electrons travel through the metal,
they fight their way through other electrons and other defects and so on, and lose energy as they
move forward. And that loss is what we pay for. And the process that is functionalized when this is happening is limited by the amount of power or current or number of electrons we put into the conduit.
While superconductivity is literally the superpower of those electrons, they can travel this time freely without being inhibited by other electrons or defects and so on. So once you get the ball rolling, they continue to go
till the system cannot sustain that property. It's quite amazing because as you say, energy is money.
And so it costs energy every time you waste some of your electricity into heating up your charger
or your phone gets hot or your computer needs to cool off. That's all loss. And superconductivity doesn't have these losses.
That's quite miraculous.
Now, what are some examples of superconductors that are actually in application now?
I think the most prominent one that affects our daily,
hopefully not our daily lives, but we encounter is a CAT scanner or MRI scanner.
And that's made of a superconducting coil, which is used to
generate magnetic fields, and it's a primary well-being tool that we have. Perhaps a more
fantastic one is the new era of transport, the maglev trains, for example, levitating trains
that go at speeds similar to aircraft. There are multiple other smaller aspects.
Superconductors allow for us to develop very sensitive devices
which can pick up signals which are minute,
which would otherwise not be possible to pick up.
And they can be applied from anywhere in IT or healthcare
or mining applications or various other things like that.
Now, why can't I have these fantastic gadgets in my home and save on my
energy bills? That's literally a million-dollar question or multi-million-dollar question.
And two interesting aspects of this. One is the fact that superconductivity itself,
as you started by telling us in the very beginning of the podcast was when that liquid-filled special device used by Kamerl
Linonis was used to cool down mercury. And similarly, we have to cool down most of these
metals to a superconducting state. So basically, you start with a normal metal where electrons are
fighting thermal barriers, but then you take it through a transition at which it starts to work in the
super way. So now for us to have that property, we need that special device to keep superconductivity
maintained at those temperatures. And that's what has inhibited its general use. And that
is in itself a very interesting problem that as human beings, we have conquered the heat.
We sit in a car, we turn the switch on, we put a newborn baby a foot away from thousands of degrees of heat and not even think about it.
At the same time, we don't have the same kind of control yet over cooling.
Superconductivity happens at lower temperatures.
However, our ways of cooling still need developing.
However, our ways of cooling still need developing.
Right. So now, after Kamerlingh Ones' initial discovery of mercury's superconductive properties, where did the research go?
Did it immediately go to, let's try to do this at warmer temperatures? Because, as you said, he had to supercool it to a staggeringly cold temperature to observe this phenomenon.
So, if you look at the history of the development
of superconductivity, we'll find two approaches. And that happens with most physical phenomena,
which is discovered. The instinct of a physicist or chemist or basic scientist is to understand
why is it happening at all? Just imagine it was happening in that era when it happened. This was
the first time it's ever been seen. One wasn't thinking necessarily about using it or controlling it just to understand what it is.
Why is it happening at all?
Or is it even true?
Can we find other examples of it?
Is it just a flaw in the measurement?
The early period went on establishing the phenomena itself,
understanding its parameters, when it happens, where it happens, how it can happen.
And then the next step, can it happen in things other than mercury? And that's when the juices start to flow. You start
to think we have different materials in which this can happen. Can this happen in alloys? Can
it happen in compounds? And as that happens, you start to talk to engineers, you start to talk to
people in other fields, and their input is what makes you realize that it can possibly be used for other things.
And the two efforts started to go in parallel but separate ways, the application of superconductivity
versus understanding of superconductivity.
And there's another very interesting lever here, which we haven't mentioned.
It's not only temperature, it's also pressure.
In fact, room temperature superconductivity is
already discovered. It's not something that's elusive anymore, except that it happens at very
high pressures. Mikhail Eremets and colleagues in 2015 already produced near room temperature
superconductivity, and now there are various examples of it. Now let's talk about why it
happens, because it's extremely different
from the ordinary conductivity of the naturally occurring elements.
You might imagine, if I supercooled something,
that the electron's motions could be inhibited
and that actually conductivity would therefore drop to zero.
And so this is really a very different and surprising phenomenon.
Can you talk us through the Nobel Prize-winning work of John Bardeen, Leon Cooper, and John
Schreifer and their theory of superconductivity?
That was a landmark moment, not just in understanding superconductivity, but understanding quantum
phenomena altogether.
So BCS theory, the basic essence of their theory is that they were able to explain that the electrons
don't travel alone like they do in a metal. They form a coherent state, what we call the Cooper
pair. The two electrons come together, and if you want to use an analogy, they are the bully on the
street. They're able to push everyone else away so they can move effortlessly in this maze of other
electrons and so on. The formation of the Cooper pair was something that was only describable and
conceptually tangible through the work of Pardon Cooper and Schrieffer in the 1950s. And in fact,
Cooper was the one who said that when two electrons are able to come together in this way,
they form a coherent state. There's a lot of electrons that become coherent, but they can be described as a set of pairs,
or a condensate that forms. So fascinating, because electrons, of course, if you're in
the quantum world, or you've studied quantum theory, are notorious for not wanting to pair up.
And the Pauli exclusion principle famously says that there's, in fact, a quantum pressure
associated with trying to jam electrons together.
They don't like it.
So this phenomenon that they discovered is extremely counterintuitive.
The collaboration with the lattice of ions left behind when the electrons start to move
away, when they pair up, now they have the opposite phenomenon where they want to bunch
together.
So you don't just get one pair.
You now have an encouraging accumulation of these electrons, and hence this runaway phenomenon of superconductivity.
It's absolutely counterintuitive and fascinating.
And that theory has held up well over the years.
Yeah, one picture that the theory builds in your mind is that of a lattice and the vibrations of lattice, what we call phonons. So you can think in terms of if this boat or ship is moving in water, and it creates a wake behind it. While it looks like it's pushing the water back while moving forward, it creates that small wake where things can get trapped, which is attractive potential. So it held up quite well
for a vast majority of superconductors. And one of the important reasons for that is that the
electron has the other property, the spin, and spin is what gives it magnetism. So everything
we have discussed now is the charge of electron. And so while we can talk of electron and its
poly-exclusion principle, we now turn to Bohr and spin and talk
about the spin itself and how opposite spin electrons can attract each other. And a Cooper
pair has a spin up, spin down configuration in the BCS theory description. Now, why does it require
so far, hopefully not forever, the super cooling? So the main barrier that one has overcome is the thermal one. So you
can think about how the heat inhibits that coherence to form. It keeps rattling things
before they can come into a coherent state. So you need to get to the temperature in which the
electrons are interacting with the other electrons rather than other vibrations. So the two things,
we have to have a cooperation between the electrons themselves and the cooperation between those electrons and the
lattice. And this lattice is driven by heat, and the lattice continues to be energetically
unfavorable till you get to the temperature at which it starts to become cooperative. So we need
the thermal side to decrease for the quantum state to fall. So that suggests that achieving room temperature superconductivity is going to be hard.
And as you said, we've seen it only under equally extreme conditions of high pressures. Do you
think it's hopeless, our attempts to achieve room temperature superconductivity without the
high pressures? Can we hold a cube of ice over open flame and
it doesn't melt? When we talk about room temperature superconductivity, that's what
we're trying to achieve here in terms of analogy. And so if that happens, usefulness aside, if you
can hold a cube over fire, it's just shockingly amazing and mind-blowing. On the other hand,
there are ways in which we can protect the state. Because we know that when we chemically make compounds,
when we change atoms,
we change the internal pressure in a material.
We increase or decrease the pressure between bonds,
between elements, and that changes the properties.
So by playing with the material,
we're able to create the same conditions as the pressure does.
We'll be right back.
Quanta Magazine is an editorially independent online publication,
launched and supported by the Simons Foundation to enhance public understanding of science.
The Simons Foundation does not influence the content of the podcast that you are listening to,
nor any of the stories covered by Quanta Magazine. Welcome back to the Joy of Why. So people have really been investigating
synthetic materials as a way to make a big breakthrough. Now, there have also been a number
of very high-profile declarations of success published in journals as prestigious as Nature of new
materials or synthetic materials that show room temperature superconductivity, but then
they were retracted. So what's going on with these kind of controversial claims?
Yes, a couple of things to say about that. The first one I want to reiterate that
it's not the room temperature superconductivity which is in question. The claims are about ambient pressure or near ambient
pressure, not about room temperature at all. The question is can it be achieved in ambient
conditions? So first of all, these high pressure experiments are extremely difficult. I am a high
pressure scientist myself, so I know the difficulty and the challenge that comes with it. At the same time, it is the most productive in this area.
And combined with the difficulty of experimental endeavour and the promise it has for applicability,
we feel that people have been rushing to give big answers,
and the whole sociology of academic ende endeavor falling in sync with this very difficult
to achieve but very promising area has produced very interesting in many ways destructive
tendencies. I would say that the vast majority of superconductivity researchers are very careful.
There is a very fun word we call them USOs. So periodically just like what happens with UFOs
all of a sudden somebody declares there's big news
for a flash and then it's gone many journals have gone into the commercial publishing world rather
than academic publishing so it's a nexus of several things which have led to these powerful
claims but as a scientist it just wets my appetite rather than discourage what i am worried about is
that the public interest and thus political interest
in this wonderful phenomena, extremely unusual, extremely promising, could get damaged if we
rely on those USOs. So can you give us a little bit of intuition briefly about what these synthetic
materials are, how they're arranged out of what we consider to be ordinary atoms. Are they sheets of different fundamental elements? How are they
constructed? Sure. They're like houses. They come in different shapes and sizes. And similar to
houses, they have different who can live in it and how comfortable they are. Superconductors
actually come in all shapes and forms. So they can come as cubic material. So think of a structure
of rock salt. You can have that cubic material
that can also be superconducting. Even gold, you can look at that. But then you can have graphite,
for instance, layers of carbon in this sense, but also other materials, and they are very weakly
bound together. So what makes graphite interesting for scientists, the reason we can write with
pencil is that those layers just fall apart. They just come onto the paper. We can write with it. That means we can put other things in
between, and that can change interactions between the sheets themselves and also between what we
put inside those sheets. So those are so-called 2D materials. Before the advent of the recent
room temperature high-pressure superconductors, there was a whole family called high TC superconductors. And these were mostly two-dimensional materials.
And two-dimensionality till today has played a very important role in finding superconductivity.
The analogy that I gave you earlier, that boat is moving and that there's a small wake which can
trap things in it. But if you imagine that all sorts of wobble, i.e. 3D,
you increase the dimensionality of emotion,
then it becomes less likely that things can get attracted and trapped
and become coherent.
You can have another simpler analogy that if you take a vat of treacle or honey
and you throw a pebble in it, it'll deform.
But since it's viscous, it cannot propagate.
So it starts to retract, and everything near it can get attracted and coherently bound.
But if you take the same thing and start to wobble it in three dimensions,
it's less likely to happen.
So two-dimensionality has played a very important role.
And we don't know if this is true for these high-pressure phases yet.
They look more to be 3D.
One of the avenues of research is, can we achieve that kind of condition in 2D materials? And that's
where most likely we're going to see zero-pressure, room-trips superconductivity is likely to come
from lower-dimensional materials. A lot of the scientists that I most admire are unafraid of failure. Their curiosity
outweighs their fear of failure. You mentioned that you're in this very challenging area of this
high-pressure superconductivity. Give us a little glimpse into your process. What is a working day
like in your laboratory? So high-pressure lab is also a low temperature lab. High pressure, because it's the
most difficult part of the process, gets highlighted. In my lab, the first thing that happens is making
the material or working with someone who makes the material and identifying that a material is
what it is. See, this is where the drama is. Even the discussion that we just had about the previous
cases, which were overblown, we don't fully agree because we don't know what the materials are.
So in my lab, we spent most of our time, sometimes more than a year even,
trying to hone down on the material is what it is.
And that's where the resilience of the researchers, the PhD students, and myself comes in
because it could turn out that after a year, this is not something we want to measure anymore.
Because it could turn out that after a year, this is not something we want to measure anymore.
And we look for new systems all the time in which this thing can happen.
And then we try to cut the sample down to size, literally, because pressure requires very small volume.
So a few tens of microns thickness and 100 micron width and so on is where the highest pressures experiments happen.
So then it comes down to attaching those famous electrodes to the samples and then trying
to put them in the pressure cells.
And then you come to the cryostat and you tell it literally the opposite of watching
water boil.
When you make a material chemically, it's a certain set of atoms arranged in a particular way and certain properties.
So why pressure is a really important tool is that when you compress something uniformly, hydrostatically, in technical words, you change those atomic distances.
And so effectively, at each pressure, you have a new material.
And at each pressure point, you can then measure all those properties.
The nice thing about this way of searching is that you can have very fine steps.
You can increase the pressure, you can release the pressure, and you can keep searching for new and new states.
Would it be fair to say that you are therefore, as you increase the pressure, looking at phase transitions?
We are looking at both. So we're looking at change and uniform change in properties
and hoping for that very drastic change. And that will be the phase transition, yes.
If one of these USOs were to become a bonafide reproducible synthetic material that shows
superconductivity at ordinary conventional
conditions that you can find in someone's apartment. This would doubtless be incredibly
lucrative. And that's because it's going to have some very serious implications socially.
Can you talk me through some of the societal ramifications of succeeding here?
It may sound biased coming from me being a superconductivity researcher,
seeding here? It may sound biased coming from me being a superconductivity researcher, but it's obvious that the ramifications of superconductivity being available in ambient conditions are going to
be transformative for all things around us. People keep talking about AI all the time. That's
nothing. Here we are talking about energy efficiencies, which are going to transform how we travel, how we
communicate. We're talking about data farms. We're talking about power grids. We're talking about
ships, planes, everything. Just like all of those things have a conductor in it,
it'll have a superconductor in it. Presumably, they're not going to immediately be available
freely across the globe. Presumably, there will be some countries that have faster access because of
their investment. That is absolutely correct. The infrastructure, both industrial and scientific
meaning laboratory and the manufacturing certainly is available only in the global north.
And there is obviously a great potential for it in some of the middle income countries,
a great potential for it in some of the middle income countries but that still leaves a huge part of globe out which cannot produce or sustain production of these kind of materials they tend
to be in geographies of eurasia australia and some other parts of the globe only but i would say
that it's not only about where they occur for For example, South Korea, which has zero iron ore
deposits, but it's one of the biggest shipmakers and steelmakers. So it's more about how you're
plugged into a system and supply and value chain. It's not only about having natural resources.
And then you have countries of Central Asia having vast resources, but they don't produce
any of them in the way they can be used. So it's more
than just having it. The discovery itself is not going to do it. Right. We have to remind ourselves
that we really are in this together. We have to get along to make the future work. You clearly
believe that superconductivity is one day possible at more ordinary conditions. Do you think we're
close? One way of talking about this, does UFO. Do you think we're close?
One way of talking about this, does UFO sighting mean that we are close to finding other aliens? Is it a symptom of that or not? One can think in that way. But from within the field,
our progress has been absolutely impressive in the last 20 years. And that has to do with our
ability to make materials and the kind of
experiments we can do now using high pressure and high fields and other conditions. So stage
is now set better than ever before to be able to find these materials. Or we have found these
materials. So how to engineer these to be an ambient condition. Fascinating. Now you have
a background not only in physics, but also anthropology and history. How do these other subjects inform your both scientific
approach and your bigger picture? I often describe myself as undisciplined,
because I'm not bound by any particular discipline. I've been lucky to have had the
chance to study, interact, and teach and work in all these areas. But fundamentally, what I'm looking at is the same thing.
For instance, if you have a bottle of water, if you hold that bottle in your hand,
reflect for a second that the hand, the bottle, and the water are all made of exactly the same elements.
But these three things have nothing in common, absolutely nothing.
Live, dead, transparent, translucent, liquid, solid, whatever you call it, there's nothing in common.
And this is where we come in, the modern day scientists, to say it's not only about what things are made of,
it's a question of how things interact.
And understanding the interaction gives rise to new properties, and they can be quite counterintuitive,
but we must find probes to measure and understand those properties,
but also find parameters to tune them like pressure, field temperature, and so on.
Human beings are like those particles.
And just imagine the pressure-temperature axis in which a human being can survive.
It's extremely narrow.
And yet, our interactions with each other and our interactions with the environment produce entire different cultures, languages, ways of thinking, and the science itself.
There's a question we here at The Joy of Why like to ask our guests, and that is, what about your research brings you joy?
The discovery and doing it with the team, with people, the colleagues,
that moment of togetherness when we find something together. Discovering something alone
is not something that I have found fun. I found that being part of a group who are working towards
some aim, going through trials and tribulations, and then the discovery happens.
And it's a reward that's shared without having to slice it up.
No, it's beautiful.
At the end of the day, science is a human endeavor.
We've been speaking with physicist Siddharth Shankar Saxena,
that's Montu to us,
on superconductors and their potential to change the world.
Thanks so much for joining us, Montu.
Thank you.
Been a pleasure.
Pleasure to have you here.
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