-
I'd like to introduce you
to an emerging area of science,
-
one that is still speculative
but hugely exciting,
-
and certainly one
that's growing very rapidly.
-
Quantum biology
asks a very simple question:
-
Does quantum mechanics --
-
that weird and wonderful
and powerful theory
-
of the subatomic world
of atoms and molecules
-
that underpins so much
of modern physics and chemistry --
-
also play a role inside the living cell?
-
In other words: Are there processes,
mechanisms, phenomena
-
in living organisms
that can only be explained
-
with a helping hand
from quantum mechanics?
-
Now, quantum biology isn't new;
-
it's been around since the early 1930s.
-
But it's only in the last decade or so
that careful experiments --
-
in biochemistry labs,
using spectroscopy --
-
have shown very clear, firm evidence
that there are certain specific mechanisms
-
that require quantum mechanics
to explain them.
-
Quantum biology brings together
quantum physicists, biochemists,
-
molecular biologists --
it's a very interdisciplinary field.
-
I come from quantum physics,
so I'm a nuclear physicist.
-
I've spent more than three decades
-
trying to get my head
around quantum mechanics.
-
One of the founders
of quantum mechanics, Niels Bohr,
-
said, "If you're not astonished by it,
then you haven't understood it."
-
So I sort of feel happy
that I'm still astonished by it.
-
That's a good thing.
-
But it means I study the very
smallest structures in the universe --
-
the building blocks of reality.
-
If we think about the scale of size,
-
start with an everyday object
like the tennis ball,
-
and just go down orders
of magnitude in size --
-
from the eye of a needle down to a cell,
down to a bacterium, down to an enzyme --
-
you eventually reach the nano-world.
-
Now, nanotechnology may be
a term you've heard of.
-
A nanometer is a billionth of a meter.
-
My area is the atomic nucleus,
which is the tiny dot inside an atom.
-
It's even smaller in scale.
-
This is the domain of quantum mechanics,
-
and physicists and chemists
have had a long time
-
to try and get used to it.
-
Biologists, on the other hand,
have got off lightly, in my view.
-
They are very happy with their
balls-and-sticks models of molecules.
-
(Laughter)
-
The balls are the atoms, the sticks
are the bonds between the atoms.
-
And when they can't build them
physically in the lab,
-
nowadays, they have
very powerful computers
-
that will simulate a huge molecule.
-
This is a protein made up
of 100,000 atoms.
-
It doesn't really require much in the way
of quantum mechanics to explain it.
-
Quantum mechanics
was developed in the 1920s.
-
It is a set of beautiful and powerful
mathematical rules and ideas
-
that explain the world of the very small.
-
And it's a world that's very different
from our everyday world,
-
made up of trillions of atoms.
-
It's a world built
on probability and chance.
-
It's a fuzzy world.
-
It's a world of phantoms,
-
where particles can also behave
like spread-out waves.
-
If we imagine quantum mechanics
or quantum physics, then,
-
as the fundamental
foundation of reality itself,
-
then it's not surprising that we say
-
quantum physics underpins
organic chemistry.
-
After all, it gives us
the rules that tell us
-
how the atoms fit together
to make organic molecules.
-
Organic chemistry,
scaled up in complexity,
-
gives us molecular biology,
which of course leads to life itself.
-
So in a way, it's sort of not surprising.
-
It's almost trivial.
-
You say, "Well, of course life ultimately
must depend of quantum mechanics."
-
But so does everything else.
-
So does all inanimate matter,
made up of trillions of atoms.
-
Ultimately, there's a quantum level
-
where we have to delve into
this weirdness.
-
But in everyday life,
we can forget about it.
-
Because once you put together
trillions of atoms,
-
that quantum weirdness
just dissolves away.
-
Quantum biology isn't about this.
-
Quantum biology isn't this obvious.
-
Of course quantum mechanics
underpins life at some molecular level.
-
Quantum biology is about looking
for the non-trivial --
-
the counterintuitive ideas
in quantum mechanics --
-
and to see if they do, indeed,
play an important role
-
in describing the processes of life.
-
Here is my perfect example
of the counterintuitiveness
-
of the quantum world.
-
This is the quantum skier.
-
He seems to be intact,
he seems to be perfectly healthy,
-
and yet, he seems to have gone around
both sides of that tree at the same time.
-
Well, if you saw tracks like that
-
you'd guess it was some
sort of stunt, of course.
-
But in the quantum world,
this happens all the time.
-
Particles can multitask,
they can be in two places at once.
-
They can do more than one thing
at the same time.
-
Particles can behave
like spread-out waves.
-
It's almost like magic.
-
Physicists and chemists have had
nearly a century
-
of trying to get used to this weirdness.
-
I don't blame the biologists
-
for not having to or wanting
to learn quantum mechanics.
-
You see, this weirdness is very delicate;
-
and we physicists work very hard
to maintain it on our labs.
-
We cool our system down
to near absolute zero,
-
we carry out our experiments in vacuums,
-
we try and isolate it
from any external disturbance.
-
That's very different from the warm,
messy, noisy environment of a living cell.
-
Biology itself, if you think of
molecular biology,
-
seems to have done very well
in describing all the processes of life
-
in terms of chemistry --
chemical reactions.
-
And these are reductionist,
deterministic chemical reactions,
-
showing that, essentially, life is made
of the same stuff as everything else,
-
and if we can forget about quantum
mechanics in the macro world,
-
then we should be able to forget
about it in biology, as well.
-
Well, one man begged
to differ with this idea.
-
Erwin Schrödinger,
of Schrödinger's Cat fame,
-
was an Austrian physicist.
-
He was one of the founders
of quantum mechanics in the 1920s.
-
In 1944, he wrote a book
called "What is Life?"
-
It was tremendously influential.
-
It influenced Francis Crick
and James Watson,
-
the discoverers of the double-helix
structure of DNA.
-
To paraphrase a description
in the book, he says:
-
At the molecular level,
living organisms have a certain order,
-
a structure to them that's very different
-
from the random thermodynamic jostling
of atoms and molecules
-
in inanimate matter
of the same complexity.
-
In fact, living matter seems to behave
in this order, in a structure,
-
just like inanimate matter
cooled down to near absolute zero,
-
where quantum effects
play a very important role.
-
There's something special
about the structure -- the order --
-
inside a living cell.
-
So, Schrödinger speculated that maybe
quantum mechanics plays a role in life.
-
It's a very speculative,
far-reaching idea,
-
and it didn't really go very far.
-
But as I mentioned at the start,
-
in the last 10 years, there have been
experiments emerging,
-
showing where some of these
certain phenomena in biology
-
do seem to require quantum mechanics.
-
I want to share with you
just a few of the exciting ones.
-
This is one of the best-known
phenomena in the quantum world,
-
quantum tunneling.
-
The box on the left shows
the wavelike, spread-out distribution
-
of a quantum entity --
a particle, like an electron,
-
which is not a little ball
bouncing off a wall.
-
It's a wave that has a certain probability
of being able to permeate
-
through a solid wall, like a phantom
leaping through to the other side.
-
You can see a faint smudge of light
in the right-hand box.
-
Quantum tunneling suggests that a particle
can hit an impenetrable barrier,
-
and yet somehow, as though by magic,
-
disappear from one side
and reappear on the other.
-
The nicest way of explaining it is
if you want to throw a ball over a wall,
-
you have to give it enough energy
to get over the top of the wall.
-
In the quantum world,
you don't have to throw it over the wall,
-
you can throw it at the wall,
and there's a certain non-zero probability
-
that it'll disappear on your side,
and reappear on the other.
-
This isn't speculation, by the way.
-
We're happy -- well, "happy"
is not the right word --
-
(Laughter)
-
We are familiar with this.
-
(Laughter)
-
Quantum tunneling
takes place all the time;
-
in fact, it's the reason our sun shines.
-
The particles fuse together,
-
and the Sun turns hydrogen
into helium through quantum tunneling.
-
Back in the 70s and 80s, it was discovered
that quantum tunneling also takes place
-
inside living cells.
-
Enzymes, those workhorses of life,
the catalysts of chemical reactions --
-
enzymes are biomolecules that speed up
chemical reactions in living cells,
-
by many, many orders of magnitude.
-
And it's always been a mystery
how they do this.
-
Well, it was discovered
-
that one of the tricks that enzymes
have evolved to make use of,
-
is by transferring subatomic particles,
like electrons and indeed protons,
-
from one part of a molecule
to another via quantum tunneling.
-
It's efficient, it's fast,
it can disappear --
-
a proton can disappear from one place,
and reappear on the other.
-
Enzymes help this take place.
-
This is research that's been
carried out back in the 80s,
-
particularly by a group
in Berkeley, Judith Klinman.
-
Other groups in the UK
have now also confirmed
-
that enzymes really do this.
-
Research carried out by my group --
-
so as I mentioned,
I'm a nuclear physicist,
-
but I've realized I've got these tools
of using quantum mechanics
-
in atomic nuclei, and so can apply
those tools in other areas as well.
-
One question we asked
-
is whether quantum tunneling
plays a role in mutations in DNA.
-
Again, this is not a new idea;
it goes all the way back to the early 60s.
-
The two strands of DNA,
the double-helix structure,
-
are held together by rungs;
it's like a twisted ladder.
-
And those rungs of the ladder
are hydrogen bonds --
-
protons, that act as the glue
between the two strands.
-
So if you zoom in, what they're doing
is holding these large molecules --
-
nucleotides -- together.
-
Zoom in a bit more.
-
So, this a computer simulation.
-
The two white balls
in the middle are protons,
-
and you can see that
it's a double hydrogen bond.
-
One prefers to sit on one side;
the other, on the other side
-
of the two strands of the vertical lines
going down, which you can't see.
-
It can happen that
these two protons can hop over.
-
Watch the two white balls.
-
They can jump over to the other side.
-
If the two strands of DNA then separate,
leading to the process of replication,
-
and the two protons
are in the wrong positions,
-
this can lead to a mutation.
-
This has been known for half a century.
-
The question is: How likely
are they to do that,
-
and if they do, how do they do it?
-
Do they jump across,
like the ball going over the wall?
-
Or can they quantum-tunnel across,
even if they don't have enough energy?
-
Early indications suggest that
quantum tunneling can play a role here.
-
We still don't know yet
how important it is;
-
this is still an open question.
-
It's speculative,
-
but it's one of those questions
that is so important
-
that if quantum mechanics
plays a role in mutations,
-
surely this must have big implications,
-
to understand certain types of mutations,
-
possibly even those that lead
to turning a cell cancerous.
-
Another example of quantum mechanics
in biology is quantum coherence,
-
in one of the most
important processes in biology,
-
photosynthesis: plants
and bacteria taking sunlight,
-
and using that energy to create biomass.
-
Quantum coherence is the idea
of quantum entities multitasking.
-
It's the quantum skier.
-
It's an object that behaves like a wave,
-
so that it doesn't just move
in one direction or the other,
-
but can follow multiple pathways
at the same time.
-
Some years ago,
the world of science was shocked
-
when a paper was published
showing experimental evidence
-
that quantum coherence
takes place inside bacteria,
-
carrying out photosynthesis.
-
The idea is that the photon,
the particle of light, the sunlight,
-
the quantum of light
captured by a chlorophyll molecule,
-
is then delivered to what's called
the reaction center,
-
where it can be turned into
chemical energy.
-
And in getting there,
it doesn't just follow one route;
-
it follows multiple pathways at once,
-
to optimize the most efficient way
of reaching the reaction center
-
without dissipating as waste heat.
-
Quantum coherence taking place
inside a living cell.
-
A remarkable idea,
-
and yet evidence is growing almost weekly,
with new papers coming out,
-
confirming that this
does indeed take place.
-
My third and final example
is the most beautiful, wonderful idea.
-
It's also still very speculative,
but I have to share it with you.
-
The European robin
migrates from Scandinavia
-
down to the Mediterranean, every autumn,
-
and like a lot of other
marine animals and even insects,
-
they navigate by sensing
the Earth's magnetic field.
-
Now, the Earth's magnetic field
is very, very weak;
-
it's 100 times weaker
than a fridge magnet,
-
and yet it affects the chemistry --
somehow -- within a living organism.
-
That's not in doubt --
a German couple of ornithologists,
-
Wolfgang and Roswitha Wiltschko,
in the 1970s, confirmed that indeed,
-
the robin does find its way by somehow
sensing the Earth's magnetic field,
-
to give it directional information --
a built-in compass.
-
The puzzle, the mystery was:
How does it do it?
-
Well, the only theory in town --
-
we don't know if it's the correct theory,
but the only theory in town --
-
is that it does it via something
called quantum entanglement.
-
Inside the robin's retina --
-
I kid you not -- inside the robin's retina
is a protein called cryptochrome,
-
which is light-sensitive.
-
Within cryptochrome, a pair of electrons
are quantum-entangled.
-
Now, quantum entanglement
is when two particles are far apart,
-
and yet somehow remain
in contact with each other.
-
Even Einstein hated this idea;
-
he called it "spooky action
at a distance."
-
(Laughter)
-
So if Einstein doesn't like it,
then we can all be uncomfortable with it.
-
Two quantum-entangled electrons
within a single molecule
-
dance a delicate dance
-
that is very sensitive
to the direction the bird flies
-
in the Earth's magnetic field.
-
We don't know if it's
the correct explanation,
-
but wow, wouldn't it be exciting
if quantum mechanics helps birds navigate?
-
Quantum biology is still in it infancy.
-
It's still speculative.
-
But I believe it's built on solid science.
-
I also think that
in the coming decade or so,
-
we're going to start to see
that actually, it pervades life --
-
that life has evolved tricks
that utilize the quantum world.
-
Watch this space.
-
Thank you.
-
(Applause)
closed TED
