Transcript Chapter 29
General Physics (PHY 2140)
Lecture 20
Modern Physics
Nuclear Energy and Elementary Particles
Fission, Fusion and Reactors
Elementary Particles
Fundamental Forces
Classification of Particles
Conservation Laws
Chapter
Chapter 2930
http://www.physics.wayne.edu/~alan/2140Website/Main.htm
General Physics (PHY 2140)
Lecture 21
Modern Physics
Elementary Particles
Strange Particles – Strangeness
The Eightfold Way
Quarks
Colored Quarks
Electroweak Theory – The Standard Model
The Big Bang and Cosmology
Chapter
Chapter 2930
http://www.physics.wayne.edu/~alan/2140Website/Main.htm
Previously…
Nuclear Physics
Nuclear Reactions
Medical Applications
Radiation Detectors
Review Problem: A beam of particles passes undeflected through
crossed electric and magnetic fields. When the electric field is switched
off, the beam splits up in several beams. This splitting is due to the
particles in the beam having different
A. masses.
B. velocities.
C. charges.
D. some combination of the above
E. none of the above
r=mv/qB
Processes of Nuclear Energy
Fission
A nucleus of large mass number splits into
two smaller nuclei
Fusion
Two light nuclei fuse to form a heavier
nucleus
Large amounts of energy are released in
either case
Processes of Nuclear Energy
Fission
A nucleus of large
mass number splits
into two smaller nuclei
Fusion
Two light nuclei fuse to
form a heavier nucleus
Large amounts of
energy are released in
either case
Nuclear Fission
A heavy nucleus splits into two smaller nuclei
The total mass of the products is less than the
original mass of the heavy nucleus
First observed in 1939 by Otto Hahn and Fritz
Strassman following basic studies by Fermi
Lisa Meitner and Otto Frisch soon explained what
had happened
Fission of 235U by a slow (low energy) neutron
236
n 235
U
92
92 U* X Y neutrons
1
0
236U* is an intermediate, short-lived state
X and Y are called fission fragments
Many combinations of X and Y satisfy the requirements of
conservation of energy and charge
Sequence of Events in Fission
The 235U nucleus captures a thermal (slow-moving) neutron
This capture results in the formation of 236U*, and the excess energy of this
nucleus causes it to undergo violent oscillations
The 236U* nucleus becomes highly elongated, and the force of repulsion
between the protons tends to increase the distortion
The nucleus splits into two fragments, emitting several neutrons in the
process
Energy in a Fission Process
Binding energy for heavy nuclei is about 7.2 MeV per nucleon
Binding energy for intermediate nuclei is about 8.2 MeV per nucleon
Therefore, the fission fragments have less mass than the nucleons
in the original nuclei
This decrease in mass per nucleon appears as released energy in
the fission event
An estimate of the energy released
Assume a total of 240 nucleons
Releases about 1 MeV per nucleon
8.2 MeV – 7.2 MeV
Total energy released is about 240 MeV
This is very large compared to the amount of energy released in
chemical processes
QUICK QUIZ
In the first atomic bomb, the energy released was equivalent to
about 30 kilotons of TNT, where a ton of TNT releases an energy
of 4.0 × 109 J. The amount of mass converted into energy in this
event is nearest to: (a) 1 g, (b) 1 mg, (c) 1 g, (d) 1 kg, (e)
20 kilotons
(c). The total energy released was E = (30 ×103
ton)(4.0 × 109 J/ton) = 1.2 × 1014 J. The mass
equivalent of this quantity of energy is:
E
1.2 1014 J
3
m 2
1.3 10 kg ~ 1g
8
2
c
(3.0 10 m/s)
Chain Reaction
Neutrons are emitted when 235U undergoes fission
These neutrons are then available to trigger fission in other nuclei
This process is called a chain reaction
If uncontrolled, a violent explosion can occur
The principle behind the nuclear bomb, where 1 g of U can release
energy equal to about 30000 tons of TNT
Nuclear Reactor
A nuclear reactor is a system designed to
maintain a self-sustained chain reaction
The reproduction constant, K, is defined as the
average number of neutrons from each fission
event that will cause another fission event
The maximum value of K from uranium fission is 2.5
Two 235U reactions, one yields 3 the other 2 neutrons
In practice, K is less than this
A self-sustained reaction has K = 1
Basic Reactor Design
Fuel elements consist of enriched
Cadmium
uranium (a few % 235U rest 238U)
The moderator material helps to
slow down the neutrons
The control rods absorb neutrons
When K = 1, the reactor is said to
be critical
The chain reaction is selfsustaining
When K < 1, the reactor is said to
be subcritical
The reaction dies out
When K > 1, the reactor is said to
be supercritical
A run-away chain reaction occurs
D2O, graphite
Schematic of a Fission Reactor
Nuclear Fusion
When two light nuclei combine to form a heavier nucleus
Is exothermic for nuclei having a mass less than ~20
(Iron is the limit, Z=26, A=56)
The sun is a large fusion reactor
The sun balances gravity with fusion energy
Sun’s Proton Cycle
First steps:
1
1
1
1
H + 11 H 21 H + e+ νe
H + 21 H 23 He + γ
2% of sun’s
energyis carried
by neutrinos
Followed by H – He or He – He fusion:
or
1
1
3
2
H + 23 He 42 He + e+ νe
He + 23 He 24 He + 11 H + 11 H
Total energy released is 25 MeV
Net Result
4 protons (hydrogen nuclei) combine to give
•
•
•
•
An alpha particle (a helium nucleus)
Two positrons
One or two neutrinos (they easily escape)
Some gamma ray photons (absorbed)
The two positrons combine with electrons to
form more gamma photons
The photons are usually absorbed and so
they heat the sun (blackbody spectrum)
Fusion Reactors
Enormous energy in a small amount of fuel
0.06g of deuterium could be extracted from 1 gal of water
This represents the equivalent energy of ~6x109 J
Fusion reactor would most likely use deuterium and tritium
2
1
H + H He + n, Q 3.27 MeV
2
1
3
2
1
0
H + H H + H, Q 4.03 MeV
2
3
4
H
+
H
1
1
2 He + n, Q 17.59 MeV
2
1
2
1
3
1
1
1
1
0
Advantages of fusion power
Fuel costs are relatively small
Few radioactive by-products of fusion reaction
(mostly helium-3 and helium-4)
Disadvantages of fusion power
Hard to force two charged nuclei together
Reactor is complex and expensive
Need high temperatures and pressures to
achieve fusion (~108 K)
need a plasma
Plasma confinement
Plasma ion density, n
Plasma confinement time,
In order to achieve a fusion reaction need
to satisfy Lawson’s criterion:
n 10 s/cm
Deuterium- tritium reactor
n 1016 s/cm3
Deuterium- deuterium reactor
14
3
So need 108 K for 1 second
Fusion Reactors - 1
Inertial confinement
Inject fuel pellets and hit them with a laser (lots
of lasers) or ion beams to heat them
Imploding pellet compresses fuel to fusion
densities
Doesn’t require plasma confinement via
magnetic fields
Requires large facility to house lasers and
target chamber.
National Ignition Facility
the facility is very large, the size of a
sports stadium
the target is very small, the size of a BBgun pellet
the laser system is very powerful, equal to
1,000 times the electric generating power
of the United States
each laser pulse is very short, a few
billionths of a second
The beams are generated in the laser bay
and deliverd to the target bay.
The National Ignition Facility
The target chamber
Fusion Reactors - 2
Magnetic field
confinement
Tokamak
design – a
toroidal
magnetic field
First
proposed by
Russian
scientists
Fusion Reactors – cont.
Tokamak Fusion Test Reactor – ITER
ITER’s proposed site layout
30.4 Elementary Particles
First we studied atoms
Next, atoms had electrons and a nucleus
The nucleus is composed of neutrons and
protons
What’s next?
Elementary particle interactions
The scattering of two electrons via a coulomb force
This virtual photon is said to mediate the electromagnetic
force. The virtual photon can never be detected because it
only lasts for a vanishing small time.
An simple example of a Feynman diagram
Interactions continued
Can have similar diagrams with other
particles and other forces
Strong force, weak force, gravity
Basic idea of exchange of a virtual particle
is the common theme.
More examples of Feynman diagrams
30.5 The Fundamental Forces in Nature
Strong Force
Short range ~ 10-15 m (1 fermi)
Responsible for binding of quarks into neutrons and protons
Gluon
Electromagnetic Force
10-2 as strong as strong force
1/r2 force law
Binding of atoms and molecules
Photon
Weak force
~ 10-6 times as strong as the strong force
Responsible for beta decay, very short range ~10-18 m
W+, W- and Z0 bosons
Gravitational Force
10-43 times as strong as the strong force
Also 1/r2 force law
Graviton
30.6 Positrons and Antiparticles
Dirac proposed the positron to solve a
negative energy problem (Dirac sea)
The general implication is that for every
particle there is an antiparticle (symmetry)
Other antiparticles:
antiproton, antineutrino
Usually denoted with a bar over symbol
Some particles are their own antiparticles
photon, neutral pion: , 0
30.7 Mesons
Part of an early theory to describe nuclear
interactions
Mass between a electron and a proton
Flavors
Charged meson: , ,mass 139.6 MeV/c2
Netral meson, 0 ,mass 135.0 MeV/c2
Lifetimes 2.6x10-8 s for ,
8.3x10-17 s for 0
More Mesons
Also have heavier mesons
Kaons ~500 MeV/c2
Etas 548 and 958 MeV/c2 (note, mass of
is greater than proton mass)
30.8 Particle Classification
(Classify the animals in the particle zoo)
Hadrons (strong force interaction, composed of quarks)
We already met the mesons (middle weights)
Decay into electrons, neutrinos and photons
Baryons, i.e. the proton and neutron (the
heavy particles)
Still other more exotic baryons:
L, S, X, all are heavier than the proton
Decay into end products that include a proton
Particle Classification – cont.
Leptons
Small or light weight particles
Are point like particles – no internal structure
(yet)
6 leptons (and their antiparticles
6 more)
Electron e, muon , tau
and their associated neutrinos: ne, n, n
Neutrinos have tiny mass, ~3 eV/c2
Some members of the Zoo
Particle Physics Conservation Laws
So far in Physics we have conservation of energy,
momentum (linear and angular), charge, spin.
Now we add more to help balance particle
reactions
Baryon number:
B = +1 for baryons, -1 for anti-baryons
Eg. Proton, neutron have B = +1
p, n , antiparticles have B = -1
B = 0 for all other particles (non-baryons)
More Conservation Laws
Lepton number
L = +1 for leptons, -1 for anti-leptons
L = 0 for non-leptons
Example for electrons:
Electron e, electron neutrino ne have Le = +1
Anti electron and antineutrino have Le = -1
Other leptons have Le = 0 BUT have their own lepton
numbers, L, L
Refer to table 30.2
Example neutron decay
Consider the decay of the neutron
n p + e + νe
+
-
Before: B = +1, Le = 0
After: B = +1, Le = +1 -1 = 0
Quiz 30.2
Which of the following cannot occur?
(a)
p+p p+p+p
(b)
n p + e + ne
(c)
μ e + n e + νμ
(d)
π μ +νμ
-
-
-
-
Quiz 30.2 - answer
The disallowed reaction is (a) because
Charge is not conserved:
Q = +2 Q = +1
Baryon number is also not conserved:
B = +2 B = +2-1 = +1
p+p p+p+p
Strangeness
Several particles found to have unusual
(strange) properties:
Always produced in pairs
- + p+ K0 + L0 but not - + p+ K0 + n
Decay is slow (indicative of weak interaction
rather than strong) Half-lives of order of 10-10
to 10-8 sec
Members of the strange club: K, L, S
More Strangeness
Explanation lies in the addition of a new
conservation law – Strangeness, S
One of the pair of strange particles gets
S=+1 the other S=-1. All other particles
get S=0. So in the previous reaction,
strangeness is conserved:
Before S=0; After S=+1-1 = 0
Second reaction violates strangeness
Example 30.6: Strangeness Conservation
Consider:
- + n K+ + S-
Before: S=0+0=0 (no strange particles)
After: K+ has S=+1, S- has S = -1 thus the
net strangeness S = +1-1 = 0
So reaction does not violate law of
conservation of strangeness, the reaction
is allowed
The Eightfold Way
Consulting table 30.2, Take the first 8
baryons and plot Strangeness vs. Charge.
We get an interesting picture. A hexagonal
pattern emerges.
If we do the same for the spin 0 mesons we
also get a hexagonal pattern.
The Eightfold Way
The Original Quark Model (in B/W)
Gell-Mann (1961) proposed hadrons have
structure, i.e. composed of a more
fundamental type of particle.
Quarks have fractional charge e/3 or 2e/3
Three types u, d, s: up, down, strange
Mesons were made of 2 quarks: q, q¯
Baryons were made of 3 quarks
But that wasn’ enough!
Soon after, experimental discrepancies
required the addition of three more quarks
Top, bottom and charm: t, b, c
And three more conservation laws: C, B, T for
charm, bottomness and topness
Properties of Quarks and Antiquarks
Fundamental Particles: Properties
Quarks
Particle
Rest Energy
Charge (e)
u
360 MeV
+2/3
d
360 MeV
-1/3
c
1500 MeV
+2/3
s
540 MeV
-1/3
t
173 MeV
+2/3
b
5 GeV
-1/3
Fundamental Particles Properties
continued
Leptons
Particle
Rest Energy
Charge
e-
511 keV
-e
-
107 MeV
-e
-
1784 MeV
-e
ne
< 30 eV
0
n
< 0.5 MeV
0
n
< 250 MeV
0
Quarks in Mesons and Baryons
We should still
be in B/W!
Color
Because of the Pauli exclusion principle
(all quarks are spin ½ particles) can’t have
three of the same particles occupying the
same state.
Example: - is (sss) so need three
different yet strange quarks
So colored quarks were proposed
Color continued
Three color charges were added
Red, green blue: r, g, b
And…three anti-colors
¯ g,
¯ b¯
antired, antigreen and antiblue: r,
Mesons have a color anticolor pair
Spin is either zero or 1 so can have ↑↑ or ↑↓
Baryons must have three different colors
Spin is ½ so have ↑↑↓ or ↓↓↑
Quarks combinations with color
Total spin is 0 or 1
Total spin is ½ or 3/2
Quantum Chromodynamics
In analogy with photons and the electromagnetic
force, an interaction between colored quarks is
the result of color force – 8 colored gluons.
The general theory is complex but explains
experimental results better.
Numerical results can be very hard to calculate
Opposite colors attract, red-antired, in analogy
with electromagnetism.
Different colors also attract though less strongly
Residual color force is responsible for nuclear
force that bind protrons and neutrons.
Interactions in the Yukawa pion and
quark-gluon models
Yukawa’s pion model
Quark QCD model
In both cases a proton-neutron
pair scatter off each other and
exchange places.
The Standard Model
History of the Universe
and of the four forces
Energy: 1028
Time:
0
1024
10-40
10-35
1021
1017
1013
1011
10-11
eV
sec
Time
Big Bang Model
A broadly accepted theory for the origin and
evolution of our universe.
It postulates that 12 to 14 billion years ago, the
portion of the universe we can see today was only
a few millimeters across. It has since expanded
from this hot dense state into the vast and much
cooler cosmos we currently inhabit.
In the beginning, there was a Big Bang, a
colossal explosion from which everything in
the Universe sprung out.
Experimental Evidence of the Big Bang
Expansion of the universe
Abundance of the light elements H, He, Li
Edwin Hubble's 1929 observation that galaxies were generally
receding from us provided the first clue that the Big Bang theory
might be right.
The Big Bang theory predicts that these light elements should have
been fused from protons and neutrons in the first few minutes after
the Big Bang.
The cosmic microwave background (CMB) radiation
The early universe should have been very hot. The cosmic
microwave background radiation is the remnant heat leftover from
the Big Bang.
Cosmic Microwave Background
99.97% of the radiant energy of the
Universe was released within the first
year after the Big Bang itself and now
permeate space in the form of a
thermal 3 K radiation field.
COBE CMB Measurement
• CMB spectrum is that of a nearly perfect blackbody with a temperature
of 2.725 +/- 0.002 K.
• Observation matches predictions of the hot Big Bang theory
extraordinarily well.
• Deviation from perfect black body spectrum less than 0.03 %
• Nearly all of the radiant energy of the Universe was released within the
first year after the Big Bang.
How did we get from there…
… to here?
Let there be light:
400,000-700,000 years