Fundamental Nuclear Physics PDF

Summary

This document provides an overview of fundamental concepts in nuclear physics, including the structure of the nucleus, radioactivity, and applications. The document also covers fundamental forces and elementary particles. It is aimed at students who are familiar with basic physics principles.

Full Transcript

Nuclear Physics
Chapter Contents
The Nucleus
Radioactivity
Applications of Nuclear Physics
Fundamental Forces and Elementary Particles
 As you will recall, the nucleus is the region of space at
the center of the atom that contains all the atom's
positive charge and almost all its mass.
The simplest nucleus is that of the hydrogen atom. The
nucleus consists of a single proton, with an electric
charge +e. All other nuclei contain neutrons in addition
to protons.
The neutron is an electrically neutral particle (its
electric charge is zero) with a mass just slightly greater
than that of the proton.
 Collectively, protons and neutrons are known as
nucleons. Nuclear physics is the study of how nucleons
interact with one another in a nucleus. The following
figure shows how nucleons are represented.
 A good way to think of a nucleus is like a bag of
marbles, with the closely packed marbles similar to the
nucleons.
This close packing in an incredibly small space results
in an enormous density of approximately 2.3 x 1017
kg/m3.
A typical nucleus, like the one illustrated in the figure
on the next slide, is described in terms of the numbers
and types of nucleons it contains.
 The atomic number, Z, is defined as the number of protons in a nucleus.
The number of neutrons in a nucleus is designated by the neutron number,
N.
Finally, the total number of nucleons in a nucleus is the mass number, A.
 Thus, the mass number is the sum of the atomic
number and the neutron number:
A=Z+N
The composition of a nucleus is expressed with special
notation. In general, the nucleus of an element X, with
atomic number Z and mass number A is written as
follows:
A
ZX

For example, the nucleus of carbon-14 is written as
follows:
 Notice that the letter C is the chemical symbol for
carbon. The atomic number, Z = 6, is written as a
subscript in front of the chemical symbol. Likewise,
the mass number, A = 14, is written as a superscript.
A similar type of notation is used for subatomic
particles—such as the nucleons. Neutrons and
protons are represented as follows:
= neutron (mass number 1, charge 0)

= proton (mass number 1, charge 1)
When nuclei contain a large number of neutrons and protons, a
circle representing the nucleus is drawn. Inside the circle we
write the symbols for neutrons and protons, along with the
number of each type of particle. An example is shown in the
figure below.
The following example shows how to write a symbol
representing a nucleus.
Because different isotopes have different numbers of neutrons, they
also have different masses.
Masses are given in atomic mass units. The atomic mass unit (u) is a
unit of mass exactly equal to 1/12 the mass of a carbon-12 atom.
In other words, the mass of one atom of. is exactly 12 u. The
value of the atomic mass unit in kilograms is as follows:
 All nuclei of a given element have the same
number of protons. However, atoms of a given
element can have different numbers of neutrons
in their nuclei.
Nuclei with the same number of protons (the
same value of Z) but different numbers of
neutrons (different values of N) are referred to as
isotopes.
For example, and.. are two isotopes of
carbon, with.6 being the most common one,
constituting 89.89% of naturally occurring
carbon.
The following table gives the mass and charge of particles in
the atom.

One of Albert Einstein's most famous results is the
relationship between mass and energy. According to Einstein,
mass and energy are equivalent, with energy equal to mass
times the speed of light squared.
This equation for mass-energy equivalence is as
follows:

As an example, let's apply the mass-energy
equivalence to a mass equal to the atomic mass
unit, 1 u.
 Substituting 1.660539 x 10−27 kg (the mass of 1 u in
kilograms) for m yields
E = mc2
= (1.660539 x 10−27 kg)(2.998 x 108 m/s2)2
= 1.492 x 10−10 J
Converting to electron volts gives
E = (1.492 x 10−10 J)(1 eV/1.6022 x 10−19 J)
= 9.315 x 108 eV
This is a significant amount of energy compared to the
13.6 eV required to ionize a hydrogen atom.
‫الكترون فولت هو وحدة قياس طاقه الحركه التي يكتسبها الكترون واحد غير‬
‫مرتبط عند تسريعه بواسطة جهد كهربائي ساكن قيمته ‪ 1‬فولت في الفراغ‪.‬‬
‫وطبقا لهذا التعريف باأللكترون فولت حاصل ضرب ‪ 1‬فولت في شحنة األلكترون‬
‫(كولوم ‪1.6023x10-19‬التي تقدر ب )أي أن‬
‫‪1 ev = 1.6023 x10 -19 volt.colum‬‬
‫بما ان ‪ 1‬فولت = ‪ 1‬جول ‪ /‬شحنة االلكترون بالكولوم نحصل علي العالقه بين األلكترون‬
‫فولت والجول وهي‬
‫‪1eV =1.6023 x 10-19 Joule‬‬
‫وحدة الجول كبيره جدا بالنسبه لتطبيقها علي األلكترونات لهذا اخترع الفيزيائيون وحدة للطاقه‬
‫الصغيره لتسهيل الحسابات عند دؤاسة الذره والجسيمات األوليه وهي وحدة االلكترون فولت‬
‫‪ 1‬جول =‪ 1‬كيلوجرام‪.‬متر‪ /2‬ثانيه‪2‬‬
 As a general rule, atomic energies are in the range of electron
volts (eV), whereas nuclear energies are in the range of
millions of electron volts (MeV), where 1 MeV = 106 eV.
We conclude, then, that 1 atomic mass unit, or 1 u, is
equivalent to an amount of energy, Eu, where
Eu = 931.5 MeV
This conversion between mass and energy will be used later
in the study of nuclear reactions.
It should be noted that all the energy in the universe is the
result of mass being converted to energy.
 Thus, if protons in a nucleus experienced only the
electrostatic force, the nucleus would fly apart.
Because this does not happen, it follows that large attractive
forces also act within the nucleus.
The attractive force that holds a nucleus together is called the
strong nuclear force.
The properties of the strong nuclear force are as follows:
The strong nuclear force acts over a very short range
(~10−15 m).
The strong nuclear force is always attractive.
The strong nuclear force does not act on electrons.
 The competition between the repulsive electrostatic forces
and the attractive strong nuclear force determines whether a
given nucleus is stable.
The following figure shows
the neutron number, N, and
the atomic number, Z, for
stable nuclei.
 Small nuclei—those with relatively small atomic
numbers—are most stable when they have nearly
equal numbers of neutrons (N) and protons (Z). For
example,.. and.. are both stable.
The condition N = Z is indicated by the straight line in
the previous figure.
As the atomic number increases, stable nuclei deviate
from the line N = Z. In fact, large stable nuclei tend to
contain significantly more neutrons than protons. An
example is , which has 110 neutrons but only 75
protons.
 Radioactivity
In fact, the largest number of protons in a stable
nucleus is Z = 83, corresponding to the element
bismuth. Nuclei with more than 83 protons are simply
not stable.
Large, unstable nuclei can decay in a number of ways.
When an unstable nucleus decays, it emits particles of
high-energy photons. The particles and photons
emitted when a nucleus decays are known as
radioactivity.
 Four types of radioactivity decay are most common.
Three involve the emission of particles, and one
involves the emission of an energetic photon.
Alpha particles (denoted by the Greek letter α)
consist of two protons and two neutrons. They are
actually the nuclei of helium atoms,.. When a
nucleus decays by giving off alpha particles, we say
that it emits α rays.
Beta particles (denoted by the Greek letter β) are
electrons that have been given off during radioactive
decay. When a nucleus gives off an electron, we say
that it emits a β− ray.
 A positron, short for "positive electron," is the
antiparticle to an electron. Positrons have the same
mass as an electron, but the opposite charge (+e). If
a nucleus gives off positrons when it decays, we say
that it emits β+ rays. In a nuclear equation, we write
a positron as e+.
A nucleus in an excited state can drop to a lower-
energy state and emit a high-energy photon known
as a gamma ray. We denote gamma rays with the
Greek letter γ.
 Radioactivity was discovered by the French physicist Antoine
Henri Becquerel (1852–1908). He observed that uranium was
able to expose photographic film, even when the film was
covered. This was proof of the penetrating ability of
radioactivity.
Typical penetrating abilities for three types of rays are as
follows:
Alpha (α) rays can barely penetrate a sheet of paper and
are stopped by a sheet of aluminum.
Beta rays (both β− and β+) can penetrate a few millimeters
of aluminum.
 Gamma (γ) rays pass right through a thin aluminum
sheet and can even penetrate several centimeters of
lead.
When a large nucleus (larger than iron) undergoes
radioactive decay, the mass of the system decreases.
The figure on the next slide shows that the mass of a
large nucleus before decay is greater than the mass of
the resulting nucleus plus the mass of the particles it
emits.
A similar change in mass
occurs with small nuclei.
For example, the mass of a
helium nucleus is less than
the mass of 2 protons and 2
neutrons that are separated
from one another, as is
indicated in the figure
below.
 This means that energy will be released if 2 protons and 2
neutrons are put together to form a helium nucleus.
In general, the difference in energy between a complete
nucleus and its separated individual parts is referred to as the
nuclear binding energy.
Nuclear binding energy is released when small nuclei are
fused together to form a larger nucleus, in a process called
fusion, and also when large nuclei decay into smaller nuclei,
in a process called fission. The energy released in fusion or
fission corresponds to a decrease in mass, according to E =
|Δm|c2.
 When a nucleus decays by giving off an α particle, it loses
two protons and two neutrons. As a result, its atomic number,
Z, decreases by 2, and its mass number, A, decreases by 4.
Symbolically, this process can be written as follows:

In this decay, X is referred to as the parent nucleus, and Y is
the daughter nucleus.
The sum of the atomic numbers on the right side of the
reaction is equal to the atomic number on the left side. The
same is true for the mass numbers.
 The following example illustrates how the energy released when a
nucleus undergoes alpha decay is determined.
 The basic process that occurs in beta decay is the
conversion of a neutron to a proton, an electron (e−),
and an antineutrino.
neutron proton + electron + antineutrino
Neutrinos have very little mass (about a hundred-
thousandth of the mass of an electron) and little
interaction with matter. Only 1 in every 200 million
neutrinos that pass through the Earth interacts with it
in any way.
 The force responsible for beta decay is known as the
weak nuclear force. This force is short range and is
important only within the nucleus of an atom.
When a nucleus decays by giving off an electron, its
mass number is unchanged (since protons and neutrons
count equally in determining A), but its atomic number
increases by 1. The process can be represented
symbolically as follows:
 In some cases a nucleus gives off a positron (e+) rather than an electron.
In the following example, the energy released when carbon-14 undergoes beta
decay is determined.
 An atom in an excited state can emit a photon when
one of its electrons drops to a lower energy level.
Similarly, a nucleus in an excited state can emit a
photon as it decays to state of lower energy.
High-energy photons emitted by nuclei are known as
gamma (γ) rays. Consider the following decay process:

The asterisk on the nitrogen symbol indicates that the
nitrogen nucleus has been left in an excited state as a
result of beta decay.
 Subsequently, the nitrogen nucleus may decay to its
ground state, with the emission of a γ ray.
Radioactive decays may occur in series. Consider an
unstable nucleus that decays and produces a daughter
nucleus. If the daughter nucleus is also unstable, it
eventually decays and produces its own daughter
nucleus, which may in turn be unstable.
In such cases, an original parent nucleus can produce a
series of related nuclei in a process referred to as a
radioactive decay series.
 An example of a radioactive decay series is shown in the
figure below.
As the figure indicates,
as uranium-235 decays,
it changes to a number
of intermediate nuclei
Before becoming the
stable
nucleus
at the end of the series,
lead-207.
 Notice that several of the intermediate nuclei in this
series can decay in two different ways—either by
alpha decay or by beta decay.
The rate at which nuclear decay occurs—that is, the
number of decays per second—is referred to as the
activity.
A highly active material has many nuclear decays
occurring in one second. For example, a typical
sample of radium (usually a fraction of a gram) might
have 105 to 1010 radioactive decays per second.
 The unit used to measure activity is the curie, named
in honor of Pierre Curie (1859–1906) and Marie Curie
(1867–1934), pioneers in the study of radioactivity.
The curie (Ci) is defined as follows:
1 curie = 1 Ci = 3.7 x 1010 decays/s
The reason for this choice is that 1 Ci is roughly the
activity of 1 g of radium.
In SI units, activity is measured in terms of the
becquerel (Bq):
1 becquerel = 1 Bq = 1 decay/s
 Applications of Nuclear Physics
Chemical reactions involve changes to the electron
clouds that surround a nucleus; nuclear reactions
involve changes to neutrons and protons within the
nucleus.
Nuclear reactions generally have no effect on chemical
reactions, and chemical reactions don't alter the
behavior of the nucleus.
Just as chemical reactions are an important part of our
everyday lives, so too are nuclear reactions.