00:00:00
[Music]
00:00:24
the world seems almost infinitely
00:00:26
complicated made up of thousands if not
00:00:29
Millions of different
00:00:34
materials throughout history people have
00:00:36
tried to collect categorize and analyze
00:00:38
them to find some underlying pattern
00:00:41
that would help simplify this seemingly
00:00:44
incredibly complicated world now at the
00:00:47
dawn of the 21st century we've made some
00:00:50
progress to achieving that long yearned
00:00:52
for
00:00:53
simplification with the use of particle
00:00:55
accelerators we are starting to
00:00:58
understand the nature of the world
00:00:59
around us
00:01:03
these machines have revealed a whole
00:01:04
array of particles which we believe may
00:01:08
be the fundamental building blocks of
00:01:11
matter but back in the 19th century
00:01:14
scientists thought that everything on
00:01:16
Earth was made of just over 80 elements
00:01:20
these elements were famously arranged in
00:01:21
a periodic table by Demitri
00:01:25
Mev at the time it was thought the
00:01:27
elements were made of indivisible
00:01:29
spheres called
00:01:32
[Music]
00:01:35
atoms but each of the elements behaved
00:01:37
in a different way did that mean that
00:01:40
there were 80 different kinds of atom
00:01:42
and if so what made them
00:01:45
different were they different shapes or
00:01:48
sizes or maybe the atoms were divisible
00:01:52
maybe they were built of even smaller
00:01:54
objects
00:01:55
[Music]
00:02:00
it was here in Cambridge that the first
00:02:02
clear evidence for smaller objects
00:02:04
inside the atom was found many of the
00:02:07
Great scientists of History walked these
00:02:09
streets and one of the greatest was JJ
00:02:12
Thompson who became the director of this
00:02:15
the old Cavendish
00:02:20
laboratory in 1896 Thompson had just got
00:02:23
his hands on this new piece of Kit now
00:02:26
it's essentially a particle accelerator
00:02:28
when this plate is heated particles are
00:02:30
emitted they're accelerated by these
00:02:33
electrodes they pass through these two
00:02:35
plates across which you can apply a
00:02:37
voltage and they hit the end of the bulb
00:02:40
here on a screen which glows so you can
00:02:42
see the beam now this is a modern
00:02:45
version of Thompson's apparatus again
00:02:47
we've got the particle accelerator and
00:02:49
there's a screen in there so you can see
00:02:50
the beam glow what Thompson did was he
00:02:53
varied the voltage across the plates and
00:02:56
he measured the amount of bending as the
00:02:58
voltage changed that allows you to
00:03:00
deduce the mass of the particles in the
00:03:03
beams now the lightest known particle in
00:03:05
Thompson's day was the hydrogen atom but
00:03:08
Thompson found from these measurements
00:03:10
that the particles in this beam are
00:03:13
almost 2,000 times lighter than hydrogen
00:03:16
atoms Thompson had discovered the first
00:03:18
subatomic particle the
00:03:24
electron the uh electron owes its
00:03:27
practicality utility to its
00:03:31
smallness it might apparently
00:03:34
Shakespeare say my use is great because
00:03:37
I am so
00:03:39
small the electron was the first
00:03:43
discovery of a fundamental particle and
00:03:45
it is interesting to realize that more
00:03:47
than a hundred years later the electron
00:03:49
is still to the best measurements we can
00:03:51
do today a fundamental letter of
00:03:53
Nature's alphabet we can use electrons
00:03:56
as ways to probe materials and look at
00:03:58
the structure in elect on microscopes or
00:04:00
in big machines like this accelerator
00:04:02
behind me pretty much all of of
00:04:04
everything we do in the in the 21st
00:04:06
century depends on understanding the
00:04:08
properties of
00:04:14
electrons Thomson had discovered that
00:04:16
the atom is not the fundamental building
00:04:18
block of matter there are smaller
00:04:20
objects inside so atoms could no longer
00:04:22
be thought of as hard indivisible
00:04:25
spheres but how do the electrons fit
00:04:27
inside the atom Thompson suggested that
00:04:30
the atom was something like this muffin
00:04:32
with the negatively charged electrons
00:04:34
embedded in a positive
00:04:37
body it would be student of Thompson
00:04:40
that proved him
00:04:41
[Music]
00:04:47
wrong the mystery of how the electrons
00:04:49
fitted inside the atom was eventually
00:04:52
solved here in Manchester in this
00:04:54
building in 1911 by Ernest
00:04:58
Rutherford Rutherford was in my opinion
00:05:01
one of the first proper particle
00:05:03
physicists because he used beams of
00:05:06
particles as projectiles to explore the
00:05:09
structure of matter now of course In
00:05:11
Rutherford's day there was no such thing
00:05:13
as a particle accelerator so he used the
00:05:15
decay of radioactive elements to produce
00:05:19
his beams of particles this is
00:05:22
Rutherford's original desk and in fact
00:05:25
if you hunt around a little bit you can
00:05:28
detect
00:05:30
traces of
00:05:32
radioactivity 100 years
00:05:37
later Rutherford asked two of his
00:05:39
students Hans Gyer and Ernest Mazen to
00:05:43
fire some alpha particles at a piece of
00:05:45
thin gold foil and see what
00:05:48
happened so imagine these tennis balls
00:05:51
are the alpha particles now if the atom
00:05:53
were as Thompson had suggested a kind of
00:05:55
amorphous blob then you'd expect the
00:05:58
alpha particles to pass right
00:06:00
[Music]
00:06:05
through and that's indeed what happened
00:06:08
to most of them but to their surprise
00:06:10
they found that around one in
00:06:15
8,000 bounce right
00:06:19
back after two years of puzzling over
00:06:22
the meaning of these results Rutherford
00:06:24
realized that in order for the alpha
00:06:26
particles to bounce back they must hit
00:06:28
something small
00:06:30
and dense so his new model of the atom
00:06:32
was a bit like the solar system with all
00:06:35
the mass concentrated at the center and
00:06:37
the electrons orbiting like planets
00:06:40
around the Sun today we know that this
00:06:43
picture isn't quite correct quantum
00:06:46
mechanics tells us that we can't know
00:06:48
precisely where the electrons are but we
00:06:51
can predict that they reside in distinct
00:06:53
shells around the nucleus Rutherford's
00:06:56
alpha particle scattering experiment was
00:06:59
remarkably direct and simple and it
00:07:01
showed the nature of what the atomic
00:07:03
structure is by the way the alpha
00:07:06
particles bounc off the atom he worked
00:07:08
out where the positive charge of the
00:07:09
atom lives Rutherford had come to the
00:07:11
astonishing conclusion that most of the
00:07:14
atom and therefore most of what we think
00:07:16
of as ordinary matter is in fact empty
00:07:19
space so if this apple with the atomic
00:07:22
nucleus the electrons would be a
00:07:25
kilometer away after discovering the
00:07:28
nucleus brother had continued doing
00:07:30
experiments firing particles at
00:07:32
different targets to delve into the
00:07:35
structure of the nucleus Itself by 1932
00:07:39
Rutherford and his colleague James
00:07:40
Chadwick had found that the nucleus is
00:07:42
made of two kinds of particles
00:07:45
positively charged protons and
00:07:47
electrically neutral
00:07:49
neutrons the discovery in these
00:07:52
experiments of neutrons uncharged atoms
00:07:55
of mass one has proved of great
00:07:58
significance
00:08:00
and importance and has given us a much
00:08:03
clearer understanding of the actual
00:08:05
structure of
00:08:08
nuclei less than a century after Mela
00:08:10
published his periodic table scientists
00:08:13
had arrived at a seemingly beautiful
00:08:16
simplification all this is made of just
00:08:19
three fundamental particles the proton
00:08:22
the neutron and the electron this was a
00:08:25
giant step forward in our understanding
00:08:27
of matter but there were still phenomena
00:08:29
that couldn't be explained in terms of
00:08:31
just these three
00:08:35
particles in the early 20th century
00:08:37
scientists recorded mysterious new
00:08:40
particles bombarding the Earth from
00:08:42
outer space they had discovered cosmic
00:08:44
rays and they rushed to study them by
00:08:48
the late 1930s they came to the
00:08:50
conclusion that the experimental results
00:08:53
could not be explained using the then
00:08:55
known fundamental particles protons
00:08:58
neutrons and
00:09:00
electrons some other more mysterious
00:09:03
particles were
00:09:05
responsible using cosmic rays to detect
00:09:07
new particles isn't particularly
00:09:09
efficient however because you never know
00:09:11
when or where they're going to turn up
00:09:13
it'll make much more sense to make your
00:09:15
own thus entered into physics this the
00:09:19
particle accelerator a way of making
00:09:22
cosmic rays in the
00:09:26
laboratory particle accelerators built
00:09:28
in the 194 40s and 50s led to the
00:09:31
discovery of many new particles given
00:09:33
exotic names like P sigmas lambdas and
00:09:39
Deltas by the mid 1960s over 80
00:09:43
apparently fundamental particles have
00:09:45
been discovered so many in fact that
00:09:47
particle physicists began to refer to
00:09:49
them as a zoo this was no better than
00:09:52
melev's periodic table eventually order
00:09:56
and elegance were restored by American
00:09:58
physicists Mary galman there was a
00:10:02
comparatively simple underlying
00:10:03
structure to all this and the
00:10:05
classification say of the strongly
00:10:07
interacting particles depended a great
00:10:10
deal on symmetries and broken in
00:10:13
particular broken symmetries approximate
00:10:16
symmetries that were
00:10:18
violated galman had noticed patterns
00:10:21
which physicists can explain in terms of
00:10:24
symmetries and by identifying the
00:10:26
underlying symmetries he found he could
00:10:29
explain the properties of the
00:10:32
particles according to him protons
00:10:35
neutrons and the whole zoo of apparently
00:10:38
fundamental particles were made up of
00:10:40
just three types of basic building
00:10:42
blocks which he named quarks just a
00:10:46
simple inspection of the uh particle
00:10:48
chart would suggest immediately the cork
00:10:51
scheme so the difficult thing was not
00:10:55
noticing the cork scheme that was
00:10:57
essentially trivial what was difficult
00:11:00
was
00:11:00
believing that it had any
00:11:07
relevance for anything for anything for
00:11:10
anything at all to happen in the
00:11:14
universe for a force must
00:11:27
act there for anything at all to happen
00:11:31
in the
00:11:31
[Music]
00:11:34
universe a force must act
00:11:41
[Music]
00:11:52
[Music]
00:12:00
we usually think of forces as moving
00:12:02
things around pulling this apple towards
00:12:05
the ground or pushing a car up a hill
00:12:08
but forces also cause the sun to shine
00:12:11
they make the ice melt in your drink and
00:12:14
they cause a plant to emerge from a seed
00:12:17
forces are the Agents of change in the
00:12:23
universe to help us understand forces
00:12:26
thousands of scientists around the world
00:12:28
have spent billions of pounds to build
00:12:31
this machine I'm standing 100 met below
00:12:34
the ground at CERN in Geneva and this is
00:12:38
the CMS detector part of the largest and
00:12:41
most complicated scientific experiment
00:12:44
ever
00:12:46
attempted this experiment will give us
00:12:48
deeper insight into the forces of nature
00:12:51
than ever
00:12:52
before it's a long way from when Isaac
00:12:54
Newton pondered the laws of gravity but
00:12:57
all part of the same story okay
