Conversations with Tyler - Philip Ball on the Interplay of Science, Society, and the Quest for Understanding
Episode Date: September 4, 2024Register for our LA Listener Meetup Philip Ball is an award-winning science writer who has penned over 30 books on a dizzying variety of subjects. Holding degrees in chemistry from Oxford and physics... from the University of Bristol, Ball's multidisciplinary background underpins his versatility. As a former editor at Nature for two decades and a regular contributor to a range of publications and broadcast outlets, Ball's work exemplifies the rare combination of scientific depth and accessibility, cementing his reputation as a premier science communicator. Tyler and Philip discuss how well scientists have stood up to power historically, the problematic pressures scientists feel within academia today, artificial wombs and the fertility crisis, the price of invisibility, the terrifying nature of outer space and Gothic cathedrals, the role Christianity played in the Scientific Revolution, what current myths may stick around forever, whether cells can be thought of as doing computation, the limitations of The Selfish Gene, whether the free energy principle can be usefully applied, the problem of microplastics gathering in testicles and other places, progress in science, his favorite science fiction, how to follow in his footsteps, and more. Read a full transcript enhanced with helpful links, or watch the full video. Recorded May 22nd, 2024. Other ways to connect Follow us on X and Instagram Follow Tyler on X Follow Philip on X Sign up for our newsletter Join our Discord Email us: cowenconvos@mercatus.gmu.edu Learn more about Conversations with Tyler and other Mercatus Center podcasts here.
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Hello, everyone, and welcome back to Conversations with Tyler.
Today I'll be chatting with Philip Ball.
I think of Philip this way.
I mean, we've had over 200 guests,
conversations with Tyler,
and I think three of them so far
have shown they are able to answer
any question I might plausibly throw their way.
Philip, I believe, is number four.
He is a scientist with degrees in chemistry and physics.
He's written about 30 books on different sciences.
Both he and I have lost count.
He was an editor at Nature for about 20 years.
His books cover such diverse topics as chemistry, physics, the history of experiments,
social science, color, the elements, water, water in China, Shartre Cathedral,
music, and more.
But most notably, he has a new book out this year, a major work called How Life Works,
a user's guide to the new biology.
Philip, welcome.
Thank you, Tyler.
Lovely to be here.
What is the situation in history where scientists have most affected
stood up to power, not counting Jewish scientists, say, leaving Nazi Germany or the Soviet Union.
Gosh, now there's a question to start with, where they have most effectively stood up to power.
You know, this is a question that I looked at in a book, it must be about 10 years old now,
which looked at the response of German physicists during the Nazi era to that regime.
And I'm afraid the response, my conclusion was the response was really not very impressive at all.
on the whole, the scientists acquiesced to what the regime wanted them to do, even if they weren't.
I mean, very few of them were actively sympathetic to the Nazi party, but they mounted no real effective opposition whatsoever.
And I'm afraid that looking at that as a case study, really, made me realize that it's actually very hard to find any time in history where scientists have actively mounted an effective opposition to that kind of imposition of.
of some kind of ideology or political power or whatever.
So history doesn't give us a very encouraging view of that.
I think, you know, that said, I think it's fair to say science is doing better these days.
I think there's a recognition that at an institutional level, science needs to be able to
mobilize its resources when it's threatened in this way.
And I think we're starting to see that certainly with climate change, which, you know,
scientists have come under fire a huge amount in that arena.
And I think there's more sort of institutional understanding of what to do about that.
Scientists aren't being so much left to their own devices to cope as best they can individually.
But I still think that there's this attitude, I think, that is still somewhat prevalent within science,
that it's a bit like we're above that.
This is exactly what some of the German physicists, particularly Werner Heisenberg,
said during the Nazi regime, that science is somehow operating in a purer sphere.
and that it's removed from all the nastiness and the dirtiness that goes on in the political arena.
I think that that attitude hasn't gone completely, but I think it needs to go.
I think scientists need to get real, really, about the fact that they are working within a social and political context
that they have to be able to work with and to be able to, when the occasion demands it,
to take some control of and not simply to be pushed around by.
And that, I think, is something that can only happen when there are institutional structures to allow it to happen so that scientists are not left to their own individual devices and their own individual sense of morality to do something about it.
So I'm hoping that science will do better in the future than it's done in the past.
Which do you think are the power structures today that current scientists, say in the Anglo world, are most enthralled to?
So you wouldn't say it's the fossil fuel companies, right?
So on climate change, many people have spoken up, but on what issues is there still this problem?
Where are the biggest biases now?
Absolutely.
There are questions being asked and concerning situations arising with the relationship between science
and what you might call commerce, really, between and industry.
So particularly, for example, in drug development in pharmaceutical companies, there have been
instances where it seems like the science has been either knowingly or unconsciously distorted
by the commercial interests involved.
You know, it's very clear that certainly pharmaceutical companies themselves
tend to underreport any work that seems to conflict with what the message they want to put out
if they're developing a drug.
So there's underreporting of negative effects or of null effects.
So I think the conflict between scientific research and the commercial interests relating to it
is one area where there are real problems to be sold.
and questions to be asked. But I think that there's also now an increasing problem simply within
the structures of academia itself. I think this is the thing that perhaps worries me most about
the way science is being steered or pushed these days, that there are these tremendous
pressures, absolutely unrealistic pressures on scientists, and particularly young scientists,
starting their careers, to publish as much as they can. And I commonly hear the complaint from
young scientists that they have no time to think anymore. You've just got to do. You've just got to
put work out there. And it has led in recent times to some quite high profile cases of
scientific misconduct where results have been, basically data has just been invented to create a
publishable piece of work. You know, and I think that even when that's not quite so
obviously fraudulent, I think there are strong pressures on scientists to find the results
that they are hoping to find. So there's a strong pressure for cognitive biases to creep in.
So this is something that ought to be eminently fixable because there is no reason science has to be
this way, that there have to be these tremendous pressures on scientists to constantly be
producing results, constantly be chasing after the, you know,
what sometimes seems like the diminishing pools of funding. There must be better ways of doing things
than this, but we haven't yet found them. And I think that's really one of the things that the
scientific community as a whole has to address. How can we reverse these unrealistic pressures
to produce in science? When it comes to policy, do you think current scientists are too safety
conscious? I wouldn't say they are, actually. Well, in policy. Now, that really depends what you mean.
I mean, there are, for example, you know, we can raise this question during the pandemic.
Was there too much caution with things like the testing of vaccines or the, you know, the various
measures that were introduced?
And of course, that is a question that became hugely politicised.
From what I saw, I think that it absolutely wasn't the case with the vaccines.
I think that the balance was was exactly right there, that they were properly tested while still
being accelerated to a degree that, you know, we absolutely needed.
and that was really a question of money more than anything else.
There was so much money thrown at the problem that it was possible to do things all at once
that normally would have been done in succession,
that the drug companies could afford to take those risks because they have the financial backing.
So I think in terms of things like that, in terms of the safety of pharmaceuticals,
I think that at the moment I see no cause for concern,
there have been worries about whether scientists have been too,
cautious in their views about climate change so that, you know, some people say, surely we knew
20 or 30 years ago that this was already a huge problem. Why weren't scientists making much more
noise about it then, as they are now, when things are getting to a really desperate stage?
And that was a process that I really saw unfold as an editor of nature we were handling a lot
of the top climate papers, you know, at that time when the worries of climate change was starting
to be raised. And I saw.
scientists going through an incredibly careful and cautious process of not wanting to be alarmist,
not wanting to claim more than the data allowed, allowed them to say with confidence.
And it felt to me as though that was right. It felt to me as though that is why today we can
say with such confidence that climate change is real and that we know something about the
causes and that it seemed clear that, you know, they're primarily anthropogenic. Because
there was that very cautious, very careful checking out of the grounds for saying that during those years.
It may well be the case that because of that caution, the alarm wasn't raised soon enough.
And it's very hard to know, you know, how to manage that discrepancy.
But I do feel that now we can be very confident in the conclusions that have been reached.
And so it's absolutely right that scientists, climate scientists in particular,
are really making strong statements and raising the alarm.
about what the future holds in this regard. So I don't think that there's too much caution there.
How far away are we from having artificial wombs that work?
Yeah, well, this has been certainly a question for the park. Well, it's actually been a question for almost
100 years now. This was something that some scientists were debating the 1920s and 1930s. In fact,
it was that debate that led to Aldous Huxley's Brave New World, which essentially talks about this
sort of in vitro gestation of whole populations. So, you know, that question has been around and
that research has been around for at least 100 years now. We're getting closer. It's an incredibly
slow process. And we're kind of coming at it from both directions now. So there are technologies,
there are techniques now that are being used to keep alive babies who are born very, very
prematurely that would previously have died. And then from the other direction,
it's becoming possible to grow embryos for longer and longer periods outside the wood.
This isn't done with human embryos because in just about all countries, that's forbidden for longer than 14 days.
But with animal embryos, it's clear that they can be grown for much longer than that,
almost to the point of full gestation, actually, certainly up until about sort of halfway through
where you've really got something like a fetus.
So we have the technologies that are getting there from these two directions.
I think the broader question is, why would we need a technology like that to do the whole job?
Certainly for humans, it's not clear that there's a call for it.
It's not clear that there's any real social driver for that sort of technology.
There is a big fertility crisis, right?
Oh, there absolutely.
Well, there is for various reasons.
Well, that's the call for it, right?
We need more people in the future at some point.
Well, if we need more people in future, I don't think, I mean, I think this.
it's one of those problems, like many problems, that is a social and economic problem that is not
going to be solved by technology. So, you know, the idea that it's questionable if this really is
the case, but if there is the case of declining fertility, it's not at all obvious that what we
therefore need is more children made by artificial means, not only because we have no means
of doing that at the moment, not only because we don't understand all of the ethical and
safety issues associated with potential technology like that, but also because if there is a
decline in fertility rates in the number of children being born in some countries, that isn't
because it's impossible. That is because of social changes that are the things that we need
to be looking at to, if we're concerned about a problem like that. I mean, it's not clear to me
that it actually is a problem at the moment.
You know, the problem of population growth is the problem that we still face.
So I'm not sure that we're going to see artificial wounds developed in the near future for human reproduction,
because I don't think that there's a clear need for them.
But isn't that a case of scientists, maybe yourself included, being too cautious?
So you understand asymptotes.
A smaller population would be fine five years from now.
But if we just keep on shrinking, it seems very, very.
Virtually every country, except Israel and parts of Africa, have gone below replacement rates, right?
Often considerably below. South Korea is at 0.7. We can't just have things shrink, shrink, shrink.
I mean, the ethical and danger implications of that are quite extreme, especially for countries with debt or a lot of retirees.
Well, I think one of the, as you say, one of the issues that that raises is more about the change in demographic where you have an increasingly aging population.
and, you know, that's also because we're living longer in a lot of countries.
And so that certainly needs to be talked about and we need to think about what the answer to that is.
I'm not sure that the answer to that is simply to have more children.
It's been predicted by, I mean, I'm no expert in demographics,
but it's been predicted by demographers for a long time that actually we were going to go
and are going to go through a population hump that it's going to peak at maybe something like
9 billion or so. And then it's predicted to decreased to something more like perhaps 6 billion or
something, which I think would be a fantastic thing because that is one of the big challenges that
we have been facing is the growth in population. It demands that that create for food production,
for energy, for economic growth generally. So I don't see any reason to believe that a,
you know, a decline from that if we reach that figure of $9 billion, that a decline from that
is going to be inherently bad in itself. And I certainly don't think that at this point there
is any reason for anyone to fear that somehow the population is going to, you know, shrink to
nothing. I don't think anyone feels that's the case. But I do feel that, as I say, it's, if there
are concerns of that sort to be raised, then what we need to be asking is what is behind
this decline in fertility. It's not fertility in the technical sense. It's not infertility. There are
issues there to some degree, but that doesn't seem to be causing the decline in birth rate. It seems
to be the choices that people are making. So why are they making those choices? That's what we really
need to understand. But it could simply be for a lot of people, kids aren't that fun, and we're just on
that asymptote forever, because that won't change. Many other things have become more fun,
like the internet or playing with AI, kids have become a bit more fun.
Maybe it's safer to raise them, but the basic joys are more or less constant.
So then we're stuck again.
Well, in my experience, kids are a lot of fun, but I think it's really important that, you know,
not everyone is made to feel as though they ought to feel that way.
So absolutely, I think if people choose not to have children, then, you know, I think there's
often a problem, actually, that if people make that choice,
it becomes stigmatized. You know, it becomes, what is your problem with children? And I
absolutely, you know, I think that's a terrible sort of attitude to take. I think it absolutely has to be
a matter of personal choice. I think for some people also, I mean, there are all sorts of reasons
why this seems to be happening. You know, for some people, it may be an economic one. Kids
cost a lot of money. Not everyone can afford that. But it's the richer societies where birth
rates fall, right? In Niger, you have seven kids to a family. Yeah, yeah. The Nordic
which have free child care, all sorts of benefits from others.
I mean, they're often between one and 1.5.
And they do many things right.
They're very nice places.
Pretty easy to raise kids there.
And they're going to disappear.
I don't know that they're going to disappear.
I think it's important to understand why it is those trends are happening
and to have some sorts of projections of how they might ultimately play out.
My understanding is certainly that in some Asian countries where birth rates are,
are falling. But I think this may be true actually in some African countries as well. There seems to be
some connection to the increasing empowerment of women, which has to be a good and important thing.
And particularly in some Asian countries, women are increasingly thinking, you know, why should I
follow the traditional route of getting married young, raising a family rather than having a career?
And also as women in those countries get greater access to education, they become.
a bit more discerning about, you know, what they're going to accept, what they're going to look for
in a partner and what they're not. And I think that too has to be a good thing. And I think that,
you know, if that's the case, if women are finding, actually, you know what, I would rather not,
you know, start a family young, get married young. I would rather actually have a career.
I would rather have my own independence. It seems to me that not only is that a positive
thing in itself. But that is something we need to understand, you know, why are they faced with
making that choice? Why are they faced with the choice of either a career or, you know, a conventional
family life? Again, these seem to me to be social questions that we need to ask that don't have
and shouldn't have a technological solution. Why isn't the human body more symmetric? So my heart's
on my left side, right? Yeah, it's pretty symmetric. It's, you know,
we do have this bilateral symmetry, but it's not perfectly so. And the question, yeah, the question of
why that is so, why would we have these small asymmetries? I'm not sure, it may be wrong,
but I'm not sure that that's something to which we have a clear answer. You know, it may be,
I mean, we have some understanding now, and it's a really interesting understanding of how
developmentally that happens, how that symmetry is broken in the body. It's really,
really fascinating to see how that happens. And when you start to think about it, it's not
obvious why it should happen at all. If we start from this symmetrical bundle of cells,
how does that symmetry get broken in the first place to create any sort of structure? So we have
some understanding of how it happens developmentally. But whether there's an adaptive benefit
or a physiological benefit to these small asymmetries that appear certainly internally in the body,
I'm really not sure.
You know, it may just in some cases be an evolutionary accident.
Now, you've written a book on invisibility.
After I read your book, I was wondering,
how much would it be worth today to be, you know, Wells is the invisible man?
Say you're an able-bodied 30-year-old man in the United States or in the UK,
and you could turn invisible at will and then be seen again.
And they don't capture you or imprison you to be studied for science.
How much is that worth?
You can go around and steal things or see people naked or what is it?
What's the equilibrium?
Yeah, exactly.
And Tyler, it's so interesting that those are the two things you, you know, alight on us.
Hey, you could do those things because that really is the message of H.U.L.'s' book.
And it's a message that he took from an ancient myth that you first crops up in Plato's Republic,
a myth of a chap called Gai Gies, who is a shepherd who finds.
a ring of invisibility. So he's just going about his job as a shepherd and then he comes across
this ring and what does he do? The first thing he does is he gets to go on the expedition of, I guess
it's sort of taking the taxes or something to the king, uses the ring to kill the king, seduce the
queen and become the ruler, a tyrant, in fact, of the population. And the message that Plato
wanted us to get from that story and that H.G. Wells wanted us to get when he rewrote it as the
invisible man is invisibility corrupts. And invisibility there is a kind of metaphor for lack of
responsibility. When you can evade responsibility for your actions, which is exactly what,
you know, you're talking about we could do if we had this rig of invisibility, that is a
corrupting capability to have. And it seems almost inevitable that that is what happens. And in fact,
it's what we see happening all the time now, particularly on the internet, where,
that anonymity, effectively, that invisibility that the internet provides, that social media can
provide to some people, or they think it provides anyway, we see that that encourages them to do
things and to say things that they would never do to someone in person. And sometimes it's even
called the Gai Gis effect. So these stories that we have told traditionally about invisibility
seem to have this kind of moral conclusion
that actually invisibility, it sounds like it would be a wonderful superpower,
but we have to really beware of that temptation
because it's a very strong corrupting influence.
I mean, look, that's, of course, that's what happened in the Lord of the Rings, right?
That was entirely the metaphor of the, you know, the ring of power there.
So I would say, I mean, you know, in military terms,
invisibility would probably be worth enormous amounts. And the military in particular is investing
in research that is trying to find materials and so forth that can confer some degree of
invisibility, whether it's to radar or to infrared or whatever. I think the message from history
and from mythology is that invisibility is a power to be very wary of. And do you think you could
turn it into a hundred million dollars or a billion dollars or how much? I think you could name your
price. If you had a technology that...
No, no, no, only you. You're invisible. No one else can do it.
Right. You can lift wallets from people's pockets, whatever you want.
You see, having written that book and having looked into the history of it, I would like to feel
that if someone came along and said, here's a ring of invisibility, it's all yours and just
yours. Do what you want with it. I would like to think that I would be like Gandalf and I would
say, no, take it away. Don't tempt me with it. Because I know where that stuff leads.
If one had it, then of course, the sky's the limit.
You could take what you like.
And that's the worry.
So, yeah, for me, I would say I would love to feel that I would resist that temptation.
Why is it that we, as evolved humans, find outer space beautiful?
Is that a coincidence?
Or is there a reason why it worked out that way?
Well, we find it, I mean, I certainly find it beautiful.
I find it beautiful to see it from Earth.
actually I find space itself, the thought of space itself terrifying.
And I feel that's really how we should see it.
And in this era of space travel, I think we're seeing that that's the case.
I mean, I was really struck by how when William Shatner was taken by Jeff Bezos on his,
one of these flights on the, is it called Blue Origin the flight?
I think so.
Yes. So he took Shatner up there. Shatner, of course, being Captain Kirk of Star Trek. And Shatner came back and said he felt this profound emptiness, really, loneliness, terrifying loneliness. He felt that he was looking at death when he looked out into space, which is absolutely not what you expect to hear from Captain Kirk, right? And I think that's right. I think that's the right way to see it. Space in reality, when we're out there, when people are out there, it's kind of.
constantly trying to kill us in all sorts of ways with radiation. You know, obviously it's
incredibly cold. It's a vacuum. So it's a deathly place. So I think that space looks beautiful to
us from Earth, from this place of safety. And it's because it's a place of safety that actually,
I think space reminds us of how precious, should remind us, of how precious this place is,
this place where we have the privilege of being able to look out onto the stars from somewhere that
gives us everything we need. And, you know, from that perspective, it is, it is or inspiring.
And, you know, that's really, I mean, I guess I feel when I, you know, when I look out on a night
like that, when I'm away from London, away from the light pollution, that what I feel is
awe in the old sense, in the 19th century sense of the sublime, this sort of slightly
terrified awe of, you know, what is out there, of our, I wouldn't say our insignificance,
but our small part in something that is just so vast. You know, when you really think about
what all these pinpricks of light represent, you know, some of them being, certainly if you
look through a telescope, some of them being entire galaxies, and we have no idea, we really
have no idea how far that goes out to. There's a beauty to it, but it's a terrifying
beauty. Speaking of terrifying, what's the hidden or you could say Straussian reading of the
Shardre Cathedral in France? Ah, well, the way I presented it in my book, I've called my book
Universe of Stone. And the idea behind that title was that in some sense, the Gothic cathedrals
and Shatra is, it's certainly my favorite. And I think it's one of the earliest of the true
Gothic cathedrals and one of the most beautiful and spectacular.
In some sense, what they represented was a model of the universe, a kind of medieval cosmology.
Because at that time, and in fact, as it happened particularly in Sharder in the Cathedral School of Shartre,
there was a resurgence of interest in the philosophy of Plato.
And Plato had this idea that the whole of the cosmos was built on principles of a sort of cosmic harmony
that involved geometric ratios between things.
And so the Gothic cathedral's themselves, they are planned according to ideal ratios, simple ratios of height and width and so on, of proportion, ratios of one to two and two to three.
And that design and that wish to sort of convey somehow this kind of sense of order and cosmic harmony, that's, I think, what we respond to even today in those places, even though we, of course, we can't see them through medieval.
lies, and we're used to seeing now gigantic constructions of all sorts, but nevertheless, for me,
the Gothic cathedrals still retained something that modern architecture hasn't managed to
capture in the sense of conveying that kind of sense of harmony and order.
So that's absolutely what the Gothic cathedrals were aiming to do.
And we know that the people who were designing them, as we would now think of them as the
architects were drawing on those platonic ideas of harmony and trying to express them explicitly
in what they did. It starts to sound like we're getting into Dan Brown territory here.
And, you know, people have claimed, and I think it's probably claimed in Dan Brown's novels,
that there are all sorts of hidden codes and so on within the Gothic cathedrals. But I think
actually the real meaning is there in plain sight, because we can see that they are built
according to these principles of proportion, that we know were important to theologians
and to the architect who worked for them.
But it's harmony plus demons, right?
Like I take the message of the cathedral to be demons rule, even the heavens.
It's a scary place to go.
You know, it's like Shatner in outer space.
I'm in the cathedral.
I'm thinking, my goodness, this is terrifying.
You know, that's exactly what Napoleon is said to have said.
The Republic, you know, the French Republic was, you know,
famously going to get rid of all this religious nonsense
and it was going to be built on principles of rebuttal.
and so on. Napoleon said that in the Gothic cathedrals, you know, even an atheist will feel
kind of uncertain of themselves because of that. And I think that's quite right. I think it's
absolutely right. I mean, I'm an atheist and I certainly had that feeling inside Charter.
And there is something, again, there is something about that sort of terrifying awe. But I think
there it's also a kind of an awe just at the sheer feat of engineering that they represent that
was done by, obviously, you know, by hand. I mean, with very sort of primitive machinery for lifting
and so on, but, you know, there was no mechanisation there. The sheer fact that these places were built
and that they are still standing so many of them after, you know, a thousand years is truly
extraordinary. And I think, I mean, you know, I thought you might be talking about the fact that
you do also literally, and some of these cathedrals have the demons around you, that you have
the gargoyles sort of up there looking down at you. I think that to some extent, and we can see
this in what was actually depicted, to some extent, there's a playfulness there that I think
people have always had, that the stonemasons had. There's a delight that they had in creating
these grotesque and often quite playful carvings, high up there, you know, sort of out of sight,
perhaps, of the priests where they, you know, they were free to let their imagination have free reign.
Why are you so much late medieval culture, science, you could say music, tapestry work, concentrated in northern France?
What was special about that region at the time?
The early Gothic era certainly did start in northern France.
So it's this region called the Iille de France.
So it's the region.
I suppose it's within, I can't remember quite what distance it's typically said to be.
But I think within about 50-mile radius of Paris.
It was absolutely that was a centre of learning at that time.
Britain, I have to say, England was very much an intellectual backwater at that time. So France was
certainly one of the regions where there was this resurgence of learning. There was some of it
happening in Germany as well, but France was a more unified country and it had been so to some
extent ever since the Emperor Charlemagne in the 9th century. So it had had this stability and
Charlemagne in fact himself was famously wanted to sort of bring about a sort of resurgence of learning.
It only really kicked off around the 11th century, 11th, 12th centuries are often called the medieval renaissance.
But I have to say that a lot of that learning was imported, was brought from the Islamic countries, from Spain, which was occupied by what were then called the Moors.
And because in the centuries preceding that era, that was the era of the golden age of learning in the Islamic nations.
They, the Islamic scholars, translated a lot of the works of the ancient Greeks, Aristotle and Plato, and many others into Arabic.
And the European scholars, many of them from France, but also from Germany and from Britain, were coming down to Spain to get hold of those works and to translate them, to learn Arabic and to translate them from Arabic to Latin.
And so that was really what created this influx of learning into Western Europe at that time.
It was coming from translations of Arabic works.
If we think of the 17th century scientific revolution in England,
putting aside the longer term role of the church and preserving manuscripts and the like,
but do you view Christianity as being a net positive or net negative behind that development?
I guess I feel in a way that's a question that it's hard to see what the counterfactuals would be to that,
because history is history, right?
So to all of the scientists in the, certainly in the 17th century, the time that's often called
the scientific revolution, Christianity was just a given. The fact that God existed,
you know, no one really in that time questioned that. They had different ways of understanding
that and of expressing that. But for those scholars, you know, that was just a given. And so
that informed everything that they were doing. So it, for some people, for example, the Anglo-Irish
scientist, as we now see him, Robert Boyle in the 17th century, it was a Christian mission to try to find out
all that we could about God's creation, about this world that God had created. That was a duty,
a Christian duty, to be curious, to be interested in everything in nature. And Boyle would make these
long lists, this sort of random list of things he wanted to find out about, things he wanted to discover.
It was really the first golden age of curiosity that time. And I think that's, to my mind, that's a better way of looking at it than calling it the scientific revolution. It was the age when curiosity was kind of liberated. So there was, in earlier times, in medieval times, there was often a sense expressed by some theologians that curiosity was something to be at best cautious of and at worst very suspicious of or even condemning of because they saw it as a sense.
a prying into things that it was not humankind's preserved to ask about.
By the 17th century, really through the process of the Renaissance and humanism and the
resurgence of learning, it had become, it became acceptable to have this almost universal
curiosity about the world. And that's absolutely something that we see in people like Boyle
and Newton and the Fellows of the Royal Society in London, but also of other scientific societies
that started elsewhere in Europe. And as I say, underpinning all of that was a profound religious faith.
So sometimes that was, you know, a motivation for that curiosity. And sometimes it was in the case of
Isaac Newton, for example, that was the framework within which he was developing his theory of
gravitation. The question with the picture that he presented of the planets, you know, revolving around the sun
and the moon revolving around the earth because of gravitational force being held there by gravity,
that was all very well. But the question was, well, how did that get started? You know,
what got them moving in the first place? We understand now that once they are moving, they'll continue to do so.
For Newton, that wasn't really a question at all, because of course, God did it. It was God's creation.
And it gave a coherence, really, to the picture that he was looking for. I mean, you can certainly find, of course, the obvious counter-example.
is the persecution of Galileo, which is often sort of misrepresented. Galileo was, to some extent,
the architect of his own misfortune, which is in no way to excuse the kind of treatment that he got
from the Catholic Church. So there were absolutely, there were tensions between this new understanding,
this new way of thinking about the world and the old idea, according to some, that, you know,
you shouldn't ask too much or that it was, well, it was just God that did it all. There were tensions there.
But I don't know that we need sort of see that as weighing in the balance, the prose and the cons.
It was simply how history was. It was simply how ideas evolved. So, yeah, I kind of, for most of the history of science, religion has been there as the backdrop, whether it's Islam or whether it's Christianity or whether it's Judaism, it's been there. And science developed.
So, you know, I think this idea that there was somehow a big tension between science,
and religion. In many ways, it's a modern construct. It's something that really only started to
become emphasized in the late 19th century for various reasons, for various polemical reasons.
I don't think it's something that we can really see throughout the history of science.
Now, you've written a book about myths. Do you think there are myths from the last 10 or 20 years
that will stick? Say the way Robin Caruso is still around as a story, or Sherlock Holmes is still
around. What would those myths be? Or have we stopped producing them? No, I'm sure we haven't stopped
producing them. So my book about myths was actually about what I call the modern myths, and it's
exactly those stories. So I begin with the earliest one that I look at from early modern times
is Robinson Crusoe. It wasn't difficult to identify the candidates for that sort of status. So
they were things like Frankenstein, Dracula, Jekyll and Hyde, Sherlock Holmes. And the latest
myth I look at in that book is Batman. So, you know, that's 100 years old now, actually. It's
amazing to think that that's the case, but it virtually is. And I don't think there's any reason
to believe that we have stopped this process of inventing modern myths. I feel that it probably
takes at least 50 years before some new narrative clearly acquires that sort of mythic status.
And I think that one of them that is now emerging that has is the zombie myth. I mean, the
idea of zombies is an old one. It started to become popularized in sort of Western culture in the
1930s. But I think it was really crystallized in the horror movie, the B-movie horror films of
the 1960s, particularly the George Romero films. So I think that we now all have a sense that,
you know, the zombie myth is something about the zombie apocalypse. And, you know, so it's,
it's not individual zombies. It's the, we're being, you know, the humanity is overrun by a horde of
of mindless zombies.
And that's, you know, so that's the sort of basis of the myth.
We sort of have that now.
And I think that we're going to continue,
I think it's inevitable that we're going to continue to develop myths.
Because what I argue in that book is that we have these,
these narratives acquire mythic status because they satisfy some need in us
to explore anxieties, social anxieties in stories,
in a way that allows us to look at them and explore.
them and think about them, myths are tools for thinking with. They don't have a moral. They don't
have a clear conclusion. They allow us to explore those anxieties. And there will always, sadly,
there will always be new anxieties that are race. We are starting to see a myth. We already have,
to some extent, a mythology of AI. That's absolutely going to be a nexus around which certain
mythologies are going to start growing. And that's, you know, that's because it's a new technology.
It's an old idea, but now that it's becoming a reality, those anxieties are really, really strong and with us and prevalent.
And so we're going to need myths to explore them.
One thing I sort of feel about that is that there are pros and cons to that because, you know, the myth that we have around AI,
and it's one that's being fed at the moment, sometimes by tech companies even, is of the AI apocalypse,
the AI take over, that we, you know, suddenly AI becomes super intelligent and it has,
has no need for us and it wipes out humanity.
That, I think, is a very convenient myth for AI companies
because it's something that's sort of out there in the indefinite future
and they can say, oh, sure, we're worrying about that.
We're taking care of that.
Whereas the real dangers and risks and things to be worried about with AI
are much more mundane things that are here and now.
Deepfakes, the production of misinformation.
Trivial but sometimes important misuses of AI
because we attribute it too much power.
Those are the things that we should really be concerned about now.
So, you know, it could be that the myths that we develop
kind of get in the way of the things we should really be worrying about in the here and now.
Let's turn now to your new book again,
How Life Works, a User's Guide to the New Biology,
which I enjoyed very much and learned a great deal from.
A simple question.
Let's say an octopus loses an arm and then the arm can grow back.
Sort of what exactly in the octopus knows to grow the arm back and where to have that growth stop?
What's regulating this response?
Because if I lose an arm, that doesn't grow back, right?
I don't have that regulator.
Yeah, yeah, yeah.
This is an extremely active area of current research.
My knowledge of octopus anatomy is not sufficient to know whether octopuses can do that.
I suspect they can't, but I may be wrong, but some creatures can.
And certainly salamanders can, axolotls can, they can regrow limbs that they have lost.
So some creatures, some complex creatures, can do this.
And we don't know exactly what enables them to do that other than that in order to do that,
you will have to have to have a reserve of something like stem cells, something that maintains a kind of stem cell-like state,
like the cells that we grew from in the early embryo.
Those are stem cells.
the cells that in the early embryo, they're able to grow into any tissue type in the body.
And we have, in our bodies, we have what are called adult stem cells, which can produce
a limited number of tissue types. So we have them, for example, in our bone marrow,
they continually produce different types of cells in our blood. But they can't, you know,
produce muscle cells or, you know, brain cells or something. Whereas, you know, in creatures that can
regenerate their limbs, they seem to have a kind of stem cell that can regrow into, you know,
many different, into all the tissue types that that limb requires. The question of how that is
done in a body that is already grown, rather than an embryo where everything is growing and
communicating and, you know, sort of finding its way together, that is a profound one that I think
we don't yet fully know the answer to. It's an area of intense research at the moment, not least
because it raises that prospect of regenerative medicine, perhaps even in humans.
If we understood how that is possible in a complex creature like an axolotl, might it not be
possible to develop some kind of capability like that in humans? And we don't know the answer to
that, but it's not obviously the case that we couldn't. Arguably, the axelotal cells are doing
computational work. Is that one way to put it? That could be one way to put it. Certainly it's
it's got to be a sort of collaborative process that the cells will have to be communicating with
each other and communicating with other cells in at least some part of the rest of the body,
you know, in order to figure out literally where they are and what they have to become as a result of that.
So that is a kind of computation of, you know, one cell communicating with those around it and so forth.
So that could be one way of thinking about it.
But we don't know the language, really, of that computation.
other than that we know that cells communicate with one another in various ways,
they can exchange chemical signals, just as they do in our synapses, in our brains.
They can exchange mechanical signals so that if you tug on the membrane of a cell,
that can induce the cell to do something or to grow or develop in a certain way that it wouldn't have done otherwise.
And they also communicate electrically.
So not just neurons, but all cell types pretty much in the human body have the potential to communicate with,
one another to sense the electric signals that other cells can produce and to respond to those.
We know the languages that cells use, but we don't really understand the kinds of conversations
that they're having in a creature like an axolotle to produce a fully formed, fully developed
replacement limb. Do you think that my cells are doing computational work in a way that,
though I cannot regrow a limb, in some manner, makes me smarter? There's this big, well, it's an
argument really. Sometimes it's a raging argument in neuroscience about whether we should think of the
brain as a kind of computer, whether it's doing computation or not. And no one agrees about this.
So I'm fairly agnostic on this, except that I have a feeling that it's not necessarily the most
useful way to think about what's going on during cognition, to think of it as being just like
the kind of computation that's going on in the, you know, electronic circuits of our laptops.
But you can see why that analogy is made, because the neurons in our brains and other cell types
are wired into networks that are clearly sending electrical pulses to one another and triggering
each other to do likewise. So, you know, it looks very much like, in some ways, like the
exchange of electrical pulses between transistors on silicon chips. But there are differences in that
process as well, sometimes profound differences. And so it's really not clear at the
moment, whether there is any straightforward or even any translation at all between the kind of
computation that is done by silicon circuits and the kind of cognitive processing that is being
done by neurons.
But you're an atheist.
Doesn't it tautologically have to be computation?
So no one ever said it had to be like a computer like I have on my desk.
But it's in some manner, you know, in the touring sense, a computation.
Well, that's the thing.
It really depends on the context you're talking about.
I mean, there are people, there are physicists, who say, well, in some sense, we can think
of everything that happens in the universe as a kind of computation of, you know, particles
interacting with one another and responding to one another.
And certainly we can develop a quantum mechanical description of what's going on in terms of
the exchange of bits of quantum information between particles.
So that's one way of looking at it.
if we mean computation in that sense of, you know, simply interactions between particles, then
sure, I think, you know, that's at the most fundamental level that seems to be what we're going
to find. But, you know, whether that means we can use computational concepts to try to
understand brain circuitry is another matter entirely. I mean, we, you know, talk in some ways,
we talk about them in similar terms. We talk about, you know, memory,
and data storage and so on, and I think there are absolutely analogies to be had there.
Whether there are strict formal parallels between those two processes, I think, is something that
is, it's yet to be decided. And perhaps more importantly, it's yet to be decided whether that will
be a useful way to think about those two processes, whether it will help neuroscientists
formulate theories and understanding of how the brain works. I think that's still a
an open question. Tell us why you reject Richard Dawkins's vision of the selfish gene, as his book
was titled. Okay. I think it's actually not quite as straightforward as rejecting it. You know,
when I was writing my book, I wanted to think, you know, clearly this has been an extremely
productive metaphor and way of portraying certainly what goes on in evolutionary biology. So I don't
think it would be fair or proper to simply say, well, that's nonsense. You know, it's time to get rid of
that. So in what way has it been useful? How to put it in the right container, I suppose. And the way I saw it as
this, I'm going to set aside the question of selfishness, which I'll come back to in a minute,
whether that's a good metaphor, but the idea that we can essentially sort of reduce everything in
biology to what the genes are doing, that is a picture that has been very productive to evolutionary
geneticists, to understand how particular mutations of genes, alleles, as they call,
different variations of a given gene, how they spread in a population. So if you get an allele arise,
the mutation of a gene that conveys some kind of property on the organism that gives it an
adaptive advantage, advantage in competition with all the others, then that allele is likely to spread
because that organism will have more offspring and so on. And all of that is, you know, this is
standard Neo-Dalwinian theory, and all of that is perfectly valid. So within that picture,
a gene-centered view of that process of how alleles spread, you know, has been useful in that
arena. The problem I have is when that comes to be seen as the basis for understanding everything
that life is. Because, you know, the problem with that is that there is no life in that picture.
It's as simple as that. I think it's really interesting that what happens there, that the genes themselves in that picture are portrayed as little agents.
You know, Richard Dawkins more or less explicitly does that. Of course, he's not saying they have any, you know, any purposes or any goals or intentions or any life, you know, in reality.
But that is how they are portrayed as though they are little organisms competing with one another, with, you know, with goals, their goal being to replicate as much as possible.
even the fact that they can replicate, you know, they're portrayed as being able to replicate.
No gene replicates. Genes are replicated. They are replicated within cells by cells.
And that's an important distinction if we're going to think about, you know, how life works.
But it may not be an important distinction to make in the context of evolutionary genetics.
So that's really where I want to sort of locate that picture of that sort of gene-centric view,
that it's a particular model.
And the selfish gene metaphor is a metaphor for that particular model for use within evolutionary genetics.
It does not speak about what genes are in a biochemical sense or what they are in a developmental sense.
And in fact, it seems fairly clear that when we're talking about genes in terms of how an organism develops
and what the role this particular bit of the DNA seems to play in that development,
That's a rather different notion of a gene to this notion of the selfish gene, you know, in a pool of different alleles, replicating.
The evolutionary gene and the developmental gene aren't necessarily the same thing.
And certainly when we try to think about a gene in molecular terms, it's become very fuzzy.
More and more fuzzy the more we've looked into what genomes really are, you know, what they really do and what our DNA does and what the different sequences of DNA do,
we find that what we think of as genes seem to overlap. There are some things that we call pseudo-greens
that maybe once were genes and aren't any longer, but maybe they can come back as genes.
There are regions outside the parts that we think of as genes that actually seem to have some
important role in development. So the whole picture becomes very fuzzy. And also within that picture,
I think the question of selfishness is important because, you know, the selfishness refers to the
tendency of a particular gene variant, an allele, to spread at the expense of other variants of
that particular gene. That's very different from the notion of a set of genes in a genome
working together to make an organism. And they have to work together to make an organism. So they're
not competing with each other. The gene that produces, you know, one enzyme isn't competing
with a gene that produces, you know, some other enzyme. They have to work together. So they're
cooperative. So I think that
selfish metaphor isn't
saying anything about what genes
do biochemically. It's
talking about that particular
model. But say I want to defend
the gene-centered view, it seems
to me that CRISPR actually works.
It's not counteracted by
some complex set of macro interactions.
If I look at genetically modified
foods, corn, rice,
and we apply genetic modification,
it's quite predictable what will result,
right? We're just not surprised.
what we get.
Yeah.
Isn't that evidence that the gene-centered view, while maybe incomplete, in predictive terms,
is really doing very well?
Like what would be a prediction your biological ecosystem view has in those cases that the
gene-centered view would not have?
Well, I don't sort of see it as a, I mean, this isn't some rival to that position.
This is an expression of what we have, an attempt to summarize what we have learned over the past
10 or 20, the 30 years, since the human genome project, really, about the way life really
functions. And within that, it's absolutely beyond question that genes have a central role to
play. Of course they do. They are the things that we inherit from one generation to the next.
And it's absolutely the case, as you say, that we can use now a gene editing technique like CRISPR
and we're getting better ones now, more accurate ones even. We can use that to address
some diseases that are caused by a gene mutation. So it's being used, for example, to cure sickle cell
anemia, which it comes about because of a mutation to one particular gene. It's possible that it might
be used for things like cystic fibrosis, for which that is also true. All of these applications
are for diseases that are in sickle cell anemia, maybe this is less so, but most of them
are rare, and they are caused by, they are traced by, they are traced by.
back to, I should perhaps say, just one particular gene or maybe, you know, maybe a couple of genes.
They're monogenic. In those situations, we can edit that gene, whether in principle in the embryo
or sometimes in the adult body as being done in sick of cell anemia. We can make that edit
and we can have a predictable response, on the whole, a predictable response from that edit.
So that's absolutely true because the condition is being caused by a single gene.
Most of the health conditions that concern the developed world, most in fact that concern the
entire world, you know, heart conditions, obesity, diabetes, as well as just about all the
traits, the physical traits we have, you know, height and intelligence and so on,
cannot be traced back to just one or two genes.
They seem to be correlated with, so differences in different individuals seem to be correlated with
differences in the genetic profile of many genes, sometimes hundreds, sometimes even thousands of genes.
So, you know, a significant part of our total complement of genes.
That is what's become clear, and that is why it's not at all clear that techniques like CRISPR gene editing
are going to be at all useful to address diseases.
like that, not only because you'd have so many targets you'd have to try to hit and you're going to
get some off target hits and, you know, that's going to cause problems, but also because all of those
genes, they're not just involved in that one thing. They're doing all kinds of tasks. They're doing
many things. And so if you start changing them around, you don't know what else you're going to be
producing, what other kind of phenotypic changes you're going to produce. And so what we need to
understand is not to identify the genes and think we can address the problem there,
because, or the, you know, the condition there, because it's arising at some other level
in the organism, at a higher level, in somehow in the way all these genes are interacting
with each other and with the other components of the genome, or with the other components of the
body, perhaps in directing cells to do something different, it's at a higher level that the
real causation of a lot of these conditions arises. And so it's there that we need to be thinking
about intervening. That's really one of the messages that I'm wanting to try to get across in the
book. So it absolutely doesn't bring into question that idea that for some conditions we can
identify specific genes that are in a real sense, the cause of that outcome. But for most of
the way life works, for most of the things we're interested in in development and in medicine,
that's not going to do the job.
We have to have a higher level understanding
of how that condition,
how that trait is coming about.
That's a more complex business
that I'm trying to kind of tease apart in my book.
I have some general questions about science for you.
So I read Carl Friston with the free energy principle.
The notion that it makes sense to understand systems
are somehow minimizing the difference between the state of affairs
prevailing at a moment
in the goals of an organism.
In psychology, this translates into some view of minimizing surprise.
Things somehow happen so that what the agent expects and what happens, those two are brought
together.
I mean, are these useful ideas, or are they just semantic reorganizations or scientists
picking up on this?
What's the status of all this work?
So this is the so-called free energy principle.
Yeah.
Yeah, the Carl Frist and Dr.
Carl is a neuroscientist at UCL here has been.
central proponent of. And I see different views on this. I think it's too early to say to what extent
it will be useful. I find it a very interesting idea and a lot of neuroscientists are looking into
ways in which they might be able to use this idea to formulate and maybe even to answer questions.
And, you know, it is something that can be formalised. There is a mathematical theory behind it.
But others have said, and I think this is a common complaint I might have.
about these kind of, in some ways, they tend to be sort of theories of everything or, you know,
theories of a very big thing, at least. Sometimes in order to be so, they become so abstract,
so mathematically abstract, that it becomes very hard to see how you relate the ideas, which are
interesting and maybe even productives of in themselves, but how to relate them to the, you know,
the lab work that a biologist, that a neuroscientist is doing. How does it relate to what they're
actually finding out?
does it help them to pose new questions and to construct and devise new experiments?
And so, you know, I think at the moment it feels to me as though it's at the stage of quite an
abstract idea that people are trying to find ways of turning into something more concrete
to address a specific problem, whether it's in neuroscience or elsewhere, or maybe even
computer science, to see whether it's going to be useful. But I, you know, I applaud the fact that
we have theories like this that are very general theories that are trying to understand something
like in this case, Carl thinks that in some sense it can be considered a generalized theory of
agency. And whether or not that's true, I think that a generalized theory of agency is absolutely
something that science needs. I have a number of friends who seem to be quite worried that they
have too many microplastics in their testicles and in their bodies more generally. Is there
serious evidence behind that worry?
I mean, whether I haven't followed the work on whether they're accumulating in the testicles,
it would be certainly concerning if that was the case.
And there has been discussions about whether plastic pollution has some kind of role in
what we seem to see as a declining in sperm count in male fertility.
In the more general sense, microplastics are absolute, there's clear evidence that it's a
problem that you see them everywhere.
You see them in the Antarctic.
you see them in marine organisms.
It's very clear that, you know, they're now a global pollution problem.
But what's the harm to me as a body?
I don't think we know yet, actually.
I mean, you know, I think that's the problem that it's, you know,
it's maybe still too early to know to what extent that's going to be a problem.
I mean, I can't help feeling that any substance that doesn't break down
that simply accumulates in the body in this way.
That doesn't sound like, you know, something that you want to have happening in your bodies
and in your tissues. It's also sometimes suggested that some of the additives, the plasticisers that are added to plastics like this, can function a little bit. They look chemically or a little bit like certain hormones, and so they can mimic hormones and induce hormonal changes in the body. And there's a lot of research going to that at the moment that I'm absolutely not an expert in, but that's one of the concerns that's being raised about them.
Michael Webb put forward the hypothesis that progress in science has declined radically in percentage terms.
And he points out, in terms of the number of scientists, we have many, many, many more,
not to mention more in China, more in India, more around the world, yet overall rates of productivity growth.
They're not higher, they're actually somewhat lower than, say, the 1960s.
We now have many more women in science.
So has there been this radical slowdown in the pace of actual discovery per scientist,
not in absolute terms, but per worker.
Like are scientists today per worker just much worse?
Just worse.
Yeah, good question.
There have been some studies that have tried to quantify this,
and there have been suggestions that actually transformational discoveries
seem to be slowing down more recently.
I mean, that seems a bit of an odd thing to say in this age of, you know,
we talked about AI, but also biotechnologies,
some of the biotechnologies that are, you know,
appearing today are so incredibly powerful and transformative. I mean, I guess I'd say, first of all,
that it's not entirely obvious that we can expect to see advances in scientific understanding
relating to productivity growth. It depends what science we're doing. Certainly if we're trying
to understand the topology of the universe, say, we can't expect to see much commercial return
from that, or certainly not directly. But I think that what I do see happening is that the
expansion of science, really, that maybe it is to some extent a victim of its own success that
you see the institutionalisation, the increasing institutionalisation of science. I think
sometimes it seems that it gives rise to a more conservative approach to things, a more cautious
approach to things, so that it becomes harder for scientists who are working and
What you might think is a more high-risk frontier of research, it becomes harder for them to do that,
becomes harder for them to find funding, becomes harder for them to get their papers published because of this increasing caution.
So there's a sort of what statisticians might say a regression to the mean.
Everything becomes a little bit more mediocre and safe.
And a lot of people in science complain that blue skies research, as they call it, research that is just saying,
What if? What happens if? What would happen? Just curiosity-driven research. That's becoming harder and harder
to do because there's an increasing demand for short-term commercial return on scientific research.
And that perhaps gives rise to a greater timidity in what science is being permitted.
So I think that that does seem to be a problem. You know, I think it's hard to know what to expect, I have to say,
because one could also argue, well, we've got all the low-hanging fruit, right?
You know, all the sort of easier stuff to figure out about how the world works and about what things
to make.
We've kind of done that.
And now we're on to the really hard stuff.
It's sort of diminishing returns.
Now, I don't know if that's true.
I think that there are still immense questions that we haven't answered in science,
but, you know, they seem to be incredibly hard ones, questions like, what is consciousness,
which, you know, we don't even know if science will ever really answer that,
whether it's a philosophical question, but it's possible that part of that decline in science
is because we're looking at more challenging problems now.
Last set of questions is about you. What's your favorite science fiction book?
Oh, that's a very nice question. I don't read as much science fiction as I used to, but I
used to be, I read all of Philip K. Dick's books, really, in my younger years.
and I think they were, they had that kind of mythic quality that I, you know, found in those older myths that I talked about.
And I also devoured the works of J.G. Ballard, which it was very interesting to me how back in those days, Ballard was just kind of dismissed as a genre writer, a science fiction writer, you know, and he never had any proper characters and so forth.
And these days, Ballard is seen as a total visionary, as he, you know, clearly is.
he saw so much of what was coming back in the 1960s.
So I would certainly name those two as two of my favorite science fiction writers.
Now, you do not have a traditional academic post, and for a long time have not had one.
If you meet a young writer who's very smart, great worker, and he or she wants to go into science writing,
what advice do you give?
Or what is it they should know that maybe they don't know?
Because you've done it.
Yeah.
Well, I guess I did it back in the day when,
one could just kind of wander randomly into it, as I did, whereas these days it's much more
professionalised, and I think that's very good, that you can now, you know, take courses in
science journalism and learn how to do things properly in a way that I had to learn on the job
in a very sort of messy way. So, you know, I absolutely think that that would be something I would
recommend get a training in science journalism because some of them are very good. They will
equip you to do what you want to do. I would say for anyone thinking about,
wanting to go into science book writing, it's really important that you aren't doing it so that you're
going to become rich. Because, I mean, it's the same for any writer, actually. You know,
this is not a way to become rich. You have to love what you're doing. You have to have a real
passion for what you're doing. And I think certainly for book writing, it feels to me like you have
to have something to say. It's not enough there to just do a translation job of a difficult field.
You really need to have something to bring to it, some insight to bring to it.
So figure out what it is you want to say and figure out what kind of voice you want to say it in.
And the way to do that is to read, to read very widely and to find out what works for you, what sort of voice works for you?
So with someone who's written about 30 science books and most of them have more than one thing to say,
like what trade is it in you that has given rise to you having so many things to say?
relative to so many of your peers.
Well, I...
What's the sauce in Pillet Ball?
The secret sauce.
I'd hesitate to put it that way when somebody of my peers
do such a fantastic job.
But I think for me, what it is is that
I have this extremely privileged position
of being able to choose a topic
and spend two, three, however many years,
really digging into it.
And so I've always felt
given that opportunity, I really want to make the best use of it that I can. And so I want to
continually be finding out about new topics to take the opportunity to discover something entirely
new. So there are some writers, not just in science, who think, who decide this is going to be my
area. I'm going to become a specialist in this area. I'm going to become known for writing about
this topic. That's fine, you know, if that's if you clearly want to do that. But for me, it's just
a wonderful opportunity to express my, and, you know, give free reign to my curiosity to find out
about these new topics. And they pop up. They suggest themselves with, you know, I would never have
imagined myself, you know, way back when working for nature, writing a book about Gothic
cathedrals that presented itself in one way or another, the more I started looking into it,
the more I thought there's a story here. And it's a story that I haven't really seen told.
a story about how the cathedrals were built in connection with an emerging new view of the cosmos,
a new view of how the world worked in the Middle Ages.
So, you know, that's the kind of thing that I look for.
I'm waiting for the sort of penny to drop of, aha, I can see something new in here.
And this is an area that I'm going to be enriched by spending two or three years finding out about.
Before I pose my last question, just again, your lady.
this book, How Life Works, a User's Guide to the New Biology?
Final query.
What will you do next?
Now, that I have to keep under wraps.
Well, I've just had a book deal pretty much agreed, and I'm going to keep that under wraps for now.
But what I can tell you is, next, next, that is the book that is going to come out later this year, which I've already written.
It's a relatively short book because it's highly illustrated.
I've done one or two others of this sort with the same publisher.
and it's an illustrated history of alchemy.
So that's what I've been writing since finishing how life works.
I've had a fantastic, as I knew I would,
have had a fantastic time writing it.
And I know that because I've worked with these people before,
it is going to look absolutely gorgeous.
So an illustrated history of alchemy.
Philip Ball, thank you very much.
Thank you.
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