Binding Energy in Radiography PDF

Summary

These lecture slides cover the basics of nuclear binding energy and its significance in radiography. The presentation includes discussions on atomic structure, atomic mass, mass defect, and ionization energy. The slides aim to provide a comprehensive understanding of these concepts, beneficial for undergraduate students in radiography.

Full Transcript

Welcome to HS1934 Lecture for Introduction to the
Diagnostic and Therapeutic Radiography Students
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attend. If not, please ask the lecturer so they can help redirect
you. Thank you.

This is expected to be a busy session today:

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Basics of Binding Energy and
Ionisation of atoms

Introduction to the Diagnostic and Therapeutic
Radiography Professions
Module code HS1934

Dr Benard Ohene-Botwe
Senior Lecturer
Diagnostic Radiography
[email protected]
Tel: +44 (0)20 7040 4387
Objective

This session will cover the definition and significance
of nuclear binding energy, ionisation process and
energy, factors affecting ionisation energy to prepare
the students for ionisation in X-ray production and
interactions with matter.
 Atomic Structure

An atom is the smallest part of a substance
that cannot be broken down chemically.
 Atomic Mass
Atomic mass (also called atomic weight) is the mass of an atom.

It can also be defined as the quantity of matter contained in an atom.

It reflects the mass of an atom’s protons, neutrons, and electrons,
although the electrons contribute very little due to their extremely small
mass.

Therefore, it is roughly equal to the number of protons plus the number
of neutrons in the nucleus (the mass number)
 Atomic Mass
Although the SI unit of mass is the kilogram (symbol:
kg), atomic mass is often expressed in the non-SI unit
called amu.

The unit of atomic mass is the atomic mass unit (amu),
also called dalton (Da or u).

One atomic mass unit (amu) is defined as one-twelfth
the mass of a carbon-12 atom.

In terms of kilograms, the mass of 1 amu
is ≈1.66×10−27 kg
 Atomic Mass
Typical masses of a proton, neutron, and electron expressed in
atomic mass units (u)

Protons and neutrons have nearly the same mass, with the neutron being
slightly heavier.

The electron’s mass is extremely small compared to protons and neutrons
Watch the first few minutes of the video
Atomic mass defect
Atomic mass defect
 Converting mass defect into binding
energy

To convert the mass defect (amu or u) into energy to
determine the binding energy, we use Einstein's
mass-energy equivalence formula:
E = Δmc2
or E = Δm x c2

Where:

𝐸 is the binding energy (in joules or MeV),
Δ𝑚 is the mass defect (in kilograms or atomic mass units, u),

𝑐 is the speed of light, 3×108 m/s.

 The difference in mass is the mass defect, which corresponds to
the binding energy that holds the nucleus together.

A larger mass defect corresponding to a more tightly bound (more
stable) atom.

Hence binding energy can be defined as the energy that holds
the atom together. It is also referred to as the minimum energy
needed to disassemble an atom into individual parts.

Electron binding energy is the measure of the energy with which
an electron is bound to the nucleus or its atomic orbital.
 Significance of binding energy
in Radiography

1. The nuclear binding energy is a key factor in determining the
stability of an atomic nucleus, with higher binding energies
indicating greater stability and lower binding energies correlating
with increased susceptibility to radioactive decay.

This concept is particularly important when considering the nuclear binding
energies of different isotopes, as they influence their stability and radioactive
properties. Understanding these properties is crucial for selecting
appropriate radioisotopes used in nuclear medicine imaging techniques such
as PET and SPECT.
 Significance of binding energy
in Radiography

2. The concept of the binding energy of electrons within an atom
plays a major role in the production of characteristic X-rays.

3. The concept of binding energy also determines how X-rays
and gamma rays (γ-rays) interact with matter.
 Ionisation process and energy
Ionization is defined as the process by which an atom or
molecule gains or loses electrons.

When an atom undergoes ionisation, it becomes a
charged atom or molecule called an ion.

Atoms become positively charged cations when they lose
electrons and negatively charged anions when they gain
electrons

Ionization energy is the amount of energy required to
remove an electron from an atom or ion in the gaseous
state.

This energy is typically equal to or greater than the
binding energy of the electron being removed, as binding
energy refers to the energy that holds the electron in its
orbital.
 Factors affecting ionisation energy
1. The distance of electron from the nucleus

Explanation: Electrons that are closer to the nucleus
are more tightly bound to the atom (higher binding
energy). This means they require more ionisation
energy to remove them from the atom. The orbital
shell closest to the nucleus is the K-shell. Next is L-
shell then M, N,O P….

Larger atoms have electrons that are farther from the
nucleus, resulting in a weaker electrostatic attraction
between the nucleus and the outermost electrons.
This makes it easier to remove an electron.
Therefore, as atomic size increases, ionization
energy generally decreases.
 Factors affecting ionisation energy
2. Higher nuclear charge
The higher the nuclear charge, the higher the ionisation energy

Nuclear charge is a measure of how positive the nucleus is

An atom with fewer electrons than protons will have a positive
nuclear charge because protons are positively charged.

An increase in the number of protons (nuclear charge) results in
higher ionisation energy as the protons in the nucleus attract
electrons more strongly.
3. Number of Electrons: For a given element, successive ionisation
energies increase as more electrons are removed.

Explanation: As electrons are removed, the positive
charge of the nucleus increasingly attracts the remaining
electrons, making it more difficult to remove subsequent
electrons. Hence, higher ionisation energy would be
required.
4. Electron shielding effect
Electron shielding refers to the effect in which the attraction between an electron and
the nucleus decreases in atoms with more than one electron, particularly when
electrons are present in different shells.

In a multi-electron atom, the inner electrons (those closer to the nucleus) "shield" the
outer electrons from the full charge of the nucleus.

This shielding weakens the attraction between the nucleus and the outermost
electrons, as the inner electrons partially block the nuclear pull.

Since the outer electrons experience less attraction to the nucleus, they are easier to
remove. As a result, less ionisation energy is required to remove the outermost
electrons.
QUESTIONS
School of Health & Psychological Sciences
City St George’s, University of London
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EC1V 0HB
United Kingdom

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