Structure of Matter Summer PDF

Summary

This document provides a lecture on the structure of matter, covering topics such as atomic structure, types of bonds (primary and secondary), and the properties of materials. The document mentions various aspects of the topic and includes questions for self-assessment.

Full Transcript

‫بسم اللة الرحمن الرحيم‬
Structure of Matter

Presented by:

Dr:Amr Sharawy

Associate professor of
dental materials
 Introduction
-The physical, mechanical and chemical
properties of any material depend mainly on:
1-Type of bond between atoms and molecules.

2-Inter-atomic distance.

3-Mannar of arrangement of atoms.

4-atomic packing.
 Atomic Structure
The atom is the basic unit of the internal structure of any material
The atom consists of:
1- Central positive nucleus [positively charged protons and uncharged neutrons].
2- Negatively charged particles [electrons] revolving around the nucleus in definite
orbits (state of energy levels or shells).

N.B;
1-Electrical state of atom: Neutral.
2-Atomic number: Number of electrons around the nucleus or number of protons
inside the nucleus.
3-Valence electrons: Electrons in the outermost shell, which determines the chemical
reactivity of the element.
4-The Atomic weight: Weight of Protons + Neutrons inside the nucleus
 1-Inter-atomic Bonding (primary bonds):
Atoms achieve a stable state by having eight electrons in their outer shell (as in inter
gases). This can be obtained by:

1-Receiving extra electrons to complete the outer shell electrons (and the atom
becomes negative ion).

2-Releasing electrons so that the outer shell has eight electrons (and the atom
becomes positive ion).

3-Sharing of electrons so that the outer shells of two or more atoms are complete.

-In solids, atoms are held together by either primary or secondary bonds.
 Types of bonds

Primary Bonds
Secondary Bonds
(Strong, Chemical)
(weak , physical)

Ionic Bond Covalent Bond Metallic Bond
A. Primary Bonds:
Def.: A bond that is formed between atoms and involves
exchange or sharing of electrons.

-Primary bond are strong chemical bond due involvement
of valence electrons.

-There are three types of primary bonds:
1) Covalent
2) Ionic
3)Metallic
1) Covalent Bonds:
Def: It is sharing of electrons.
- The hydrogen molecule, H2, is an example of covalent bonding.
- The two atoms approach one another and the orbitals of the electrons begin to
overlap,
- The two electrons are shared between the two nuclei. The shared electrons will
spend most of their time in the region where the orbitals overlap.
- Double and triple covalent bonds are possible, where two or three pairs of
electrons are shared between atoms.
- Examples of covalent bonds are fluorine, hydrogen, diamond ,polymers and
ethylene.
Characteristics of covalent bonds:
Very strong.
Directional
Insulators.
Resist inorganic solvents.
2) Ionic Bonds: result from the electrostatic attraction between ions of unlike
charge.
-The classic example is sodium chloride (Na+ C1-), because the sodium atom contains one
valence electron in its outer shell and the chlorine atom has seven electrons in its outer
shell, the transfer of the sodium valence electron to the chlorine atom then the attraction
of positive and negative ions results in the stable compound Na+ Cl-.

Characteristics of ionic solids:
1-Heat resistant and insulator as solid.
2-Insoluble in organic solvents.
3-Easily dissolved in ionic solutions such as water, acids and alkalis, and dissociate into their
constituent ions in solutions which in their turn can conduct an electric current.
4-Non directional
5-Basic bond for glasses and ceramics 6-Low coefficient of thermal expansion
e.g In dentistry, ionic bonding exists in some dental materials, such as gypsum and Zinc
phosphate cements.
3)Metallic Bonds:
Def. : It is the attraction between +ve cores and free electrons or electron
cloud".
-It occurs in metals.

Characteristics of the metallic bonds:
The free mobility of electrons contributes to the following properties of metals:
1-High thermal and electrical conductivity due to the presence of free electrons.
2-Opaque due to absorption of light by free electrons.
3-Lustrous due to reflection of light by free electrons
4-High strength and hardness.
5-It leads to crystalline arrangement in metals
6- Low coefficient of thermal expansion
B. Secondary Bonds (Van der Waals forces)
"intermolecular bonds" "Dipole bonds":
Def.: A bond that involves attraction between molecules.
-These forces are physical, weak and arise from the polarization of molecules i.e.
formation of electrical dipoles followed by physical attraction between the opposite
poles.

-Hydrogen bridges between water molecules are the most important example.

Characteristics of secondary bonds:
A solid whose molecules are bonded together by Vander Wall forces has:
1. Low strength and hardness.
2. Low thermal resistance.
 Distinction should be made between: Atomic solids, such as
diamond, and molecular solids, such as polymers, where in
molecular solids, the covalently bonded molecules are held
together by Van der Waals forces which control the properties.

Molecular
Atomic solids
solids
Primary Bonds Secondary forces hold
No Secondary forces molecules
High strength and Low strength and hardness
hardness

High melting temperature Low melting temperature

Low coefficient of High coefficient of thermal
thermal expansion expansion
Example: Metals, diamond
Example: Polymers, waxes
Ceramics
 2-Inter-atomic distance (I.A.D.):
The space between atoms is caused by:
1- Inter-atomic repulsive force which results from the electrostatic
fields of each atom.
2- Inter-atomic attractive forces which results from different types of
bonding.

The equilibrium distance is that distance at which the repulsive and
attractive forces are equal.
N.B. Application of an external force to a solid can displace atoms
from the equilibrium position, and change the I.A.D.
 State of Matter
Matter can be classified into gas, liquid, and solid.
A. Gases B. Liquids C. Solids
The molecules in gases can In liquids, In solids, the atoms
move freely and their with the have

1-largest interatomic distance 1-there is less inter- 1-the least I.A.D.
in between atomic distance

2-the energy is high. 2-Less energy 2-the least energy.
 3-Mannar of arrangement of atoms.
The structure of solids
Properties of materials depend on the arrangement of their atoms.
Types of Solids:
a) Crystalline solids. b) Amorphous solids.

a) Crystalline Solids:
Def.: Solids in which their is a regularity and repetition in the arrangement of their atoms i.e (atoms are regularly arranged in a
space lattice).

A space lattice :the arrangement of atoms in three dimensions such that every atom has a position similar to every other atom.

The atoms may be held together by ionic bonds as in sodium chloride, covalent bonds as in diamond, or metallic bonds as in
metals.
 Types of crystal lattice or crystal systems:
-Atomic packing in a crystal may take many configurations; the simplest way to
study it is to consider a unit cell.

Unit cell :which is the smallest repeating unit in the space lattice.
-There are about 14 different types of space lattice but only few are of dental
interest. The simplest way to study these types, is to consider a unit cell.

-Unit cells are classified according to:
a) The length of their axes (a ,b , c ).
b) The interfacial angles( , ,  )
 System Axes Axial angles

Cubic a=b=c α=β=γ=90°

Tetragonal a=b≠c α=β=γ=90°

Orthorhombic a≠b≠c α=β=γ=90°

Monoclinic a≠b≠c α=β= 90°≠γ

Triclinic a≠b≠c α≠β≠γ≠90°

Hexagonal a=b≠c α=β=90°;γ=120

Rhombohedral a=b=c α≠β≠γ≠90°

Types of crystal lattice systems
 1-Cubic system:
The cubic space lattice is characterized by having axes that
have equal lengths and they meet at right angle
Cubic a=b=c α=β=γ=90°

There are three types of the cubic system:
 Hexagonal a=b≠c α=β=90°;γ=120
2-Hexagonal System:

Simple hexagonal Close packed Hexagonal

19
b) Amorphous Solids:
Amorphous means without specific form or shape.

-Def.: Solids in which there is no regularity and no repetition in the
arrangement of their atoms.

-Gases and liquids are amorphous substances.

-Some solids like glass and waxes are amorphous because of the random
arrangement of their atoms, yet their atoms may form a short range order
arrangement without repetition.
 Comparison between crystalline and amorphous materials

Crystalline solids Amorphous solids
1) Have definite melting temperature. 1) No definite melting temperature (gradually soften on heating

and gradually harden on cooling).. The temperature at
which they first form a rigid mass upon cooling
or soften upon heating is called glass transition
temperature Tg

2) No regular unit cell but may have a short range of regularity
2) Have regular unit cell with repetition.
but no repetition. i.e. no repetition no regularity

3) Low internal energy.
3) Higher internal energy due to random arrangement of atoms.
 4-Atomic Packing Factors:
Definition: It is the fraction of the space of the structure unit occupied by the
atoms and is calculated by: volume of atoms inside the unit cell
Atomic packing factor= volume of unit cell

A-For the simple cubic system = 0.54 which indicates that nearly 50% of the
space is free.
B-Body centered cubic (bcc) = 0.68
C-Face centered cubic (fcc) = 0.74
D-Closed packed hexagonal (cph) = 0.74
-Materials having higher atomic packing factor usually have higher density ,
stability and strength properties.
-Most dental alloys crystallize in fcc or hcp space lattices.

simple cubic Body centered cubic

Face centered cubic Closed packed hexagonal
 Imperfections in crystalline solids

Theoretical strength
Vs
Actual strength

Materials contain some defects or imperfections
which decrease the actual strength
 1- Point Defect:

Vacancy: Interstitial Impurity:
A missing atom due to imperfect Extra atom may be lodged
packing during crystallization within the crystal
Thermal vibrations when heated

Strength Strength
2- Line Defect:
e.g: Dislocation: displacement of a row of
atoms from their normal positions in the
lattice

Strength
3- Plane Defect:
e.g. Grain Boundaries in metals
Strength
 Polymorphism

the existence of the material in different
physical forms while having the same
chemical structure
For Organic materials → Isomerism
e.g Gutta percha
For Inorganic materials → Allotropy
e.g Silica (SiO2)
Polymorphism
The existence of the same chemical compound in different crystalline (physical) forms.

Polymorphism

Allotropy Isomerism
Occur in crystalline inorganic materials Occur in amorphous organic materials
e.g. Silica in dental investment e.g. Natural rubber and gutta perca

Silica (SiO2)
-It is an important example for allotropy in dentistry.
-It exists in nature in four different allotropic forms, which are; Quartz, Tridymite,
Crystobalite and Fused quartz.
-Each form has different physical properties due to their difference in crystalline
structure but all are chemically SiO2.
-On heating of the four forms ,two types of transformation take place:
 * Polymorphism: e.g Silica
1-Reconstructive Transformation:

870ºC 1470ºC 1713ºC
Fused
Quartz Tridymite Crystobalite
Quartz

Hexagonal Rhombohedral Cubic Amorphous
 2-Displacive transformation
870ºC 1470ºC 1713ºC
β- β- Fused
β- Quartz Quartz
Tridymite Crystobalite

Hexagonal Rhombohedral Cubic Amorphous

573ºC 160ºC 220ºC

α-Quartz α-Tridymite α-crystobalite

(SiO2) (SiO2) (SiO2)
 Comparison between reconstructive and
displacive transformation
Reconstructive Transformation Displacive Transformation

-Break down of atomic bonding -No break down of atomic bonding
followed by reconstruction of only displacement of atoms giving
new space lattice. the same space lattice but with
larger volume.

-Needs high thermal energy. -Needs less thermal energy.

-Slow transformation. -Rapid transformation.

--The manufacturer selects one -The selected type compensates
of the types to be used in the for the solidification shrinkage of
dental investment the metal during casting.
 Correlation between atomic structure
and materials properties:
1.Density is controlled by atomic weight, atomic radius, and the atomic packing
factor.
2.Thermal expansions of materials with comparable atomic packing factors
vary inversely with their melting temperature.
3.Electrical and thermal conductivity are very dependent on the nature of the
atomic bonds [ionic/covalent/metallic].
4.Melting and boiling temperatures can be correlated with the strength of the
bond. Generally, materials with weaker bonds have low melting point
5.Strength can be correlated with the type of the bond.
6-The arrangement of atoms classify the materials into crystalline or
amorphous structure.
7-Atomic structures are generally stronger than molecular structures because
primary bonds control the properties.
 Self assessment questions
I. Choose the correct answer(s):

1-Fraction of space occupied by the atoms in a unit cell of a space lattice is:
a. Interatomic distance. b. coordination number.
c. Atomic packing factor. d. Atomic weight.
2-Amorphous solids are characterized by having:
a. High internal energy. b. Random and short order arrangement
c. Definite melting temperature. d. Specific shape and form in their structure.
3-Crystalline solids are characterized by having:
a. Low internal energy. b. Random and short order arrangement
c. Glass transition temperature. d. Specific shape and form in their structure
4-For secondary bond to occur, there must be:
a. Electrons cloud. b. Electrons share.
c. +ve core. d. Dipole.
5-Metals are electrical conductor due to presence of:
a. Cloud of electrons. b. +ve & -ve ions.
c. Shared electrons. d. All of the above.
II. Give reasons for:

(1) Theoretical strength of the materials is higher than the actual strength.
(2) High electric conductivity of metals.
(3) Molecular solids are weaker than atomic solids
(4) Ceramics are heat resistant.
(5) Ceramics have high melting point.