Lecture 2 Dental Biomaterials PDF

Summary

This lecture provides an overview of dental biomaterials, focusing on the structure of matter and its role in material properties. It covers topics like primary and secondary bonds, and examples in dental applications.

Full Transcript

Dental biomaterials I
course # DEN-DBM201-1

Lecture 2:
Structure of Matter
DR. Fahiem M. El-shamy
Lecturer in Dental Biomaterials
Faculty of Dentistry, Menoufia National University
OBJECTIVES
After reading this chapter, the student should be able to:
1. Describe the close relation between the atomic basis
of a material and its properties..
2. Compare and contrast ionic, covalent, metallic
bonds and Secondary bonds their role in restorative
dental materials.
3. Describe the differences between molecules and
lattices and cite which restorative materials occur in
which.

10/6/2024 DR/ FAHIEM M. EL-SHAMY
 Matter
MATTER is any substance which has
mass and occupies space.

Atom
Is the unit structure of matter, the smallest unit of an
element, having all the characteristics of that element and
consisting of

1. Protons
Nucleus
2. Neutrons

3. Electrons
There is a close relation between
the atomic basis of a material and
its properties.

10/6/2024 DR/ FAHIEM M. EL-SHAMY
 Interatomic attraction

10/6/2024 DR/ FAHIEM M. EL-SHAMY
Atoms achieve a stable state by having 8 electrons in
their outer shell (valence shell).
This obtained by:
A) Receiving extra electrons atoms and become
negative ion.
B) Releasing electrons and become positive ion..
C) Sharing of electrons.

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 In solids, atoms are held together by either

1. Primary bonds (Chemical).

2. Secondary bonds (Physical).

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 Interatomic Bonding

Primary Secondary
(Chemical) bond (Physical) bond

Ionic Covalent Metallic Van der
Hydrogen
Bonds Bonds Bonds Waals
Bonds
Forces
 Primary
(Chemical) bond

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 1- Ionic bonds:
It is the attraction of positive
and negative ions.
Occurs between metal and
nonmetal
 The classic example is sodium
chloride (Na+Cl-).
 In dentistry, ionic bonding
exists in some dental
materials, such as gypsum and
phosphate-based cements.
 Zinc phosphate cement Gypsum products
Chemically “CaSO4.l/2H2O",

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10/6/2024 DR\ FAHIEM M. EL-SHAMY
Characteristics of ionic bonds:
 Strong bond.
 Heat resistant.
 Insoluble in organic solvents.
 Easily dissolved in ionized solvents such as
water, acids, and alkalis.
 Can conduct electricity in solution.
 2- Covalent bonds:
 It is sharing of electrons.
 Two valence electrons are shared by adjacent atoms.
 Occurs between Non-metal + non-metal
 Example , H2 and many organic compounds (C & H), such
as dental resin

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 Dental resin
(Type of Dental polymer)
Composite resin Acrylic resin
Uses:
Denture base& special tray &
removable ortho. Appliance.

Composite resin (organic resin
matrix & inorganic filler)

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  Characteristics of covalent bonds:
 Strong bond.

 Water insoluble

 soluble in organic solvent
 Insulator (electrical & thermal).
 Basic bond of polymer.

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 3- Metallic bonds:
 Atoms give up their valence electrons which form an
electron cloud.

 Metallic bond is the attraction between +ve core and –ve
free electrons or electron cloud.
 It occurs in metals (dental amalgam, casting alloys, dental
wrought wires).

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10/6/2024 DR/ FAHIEM M. EL-SHAMY
 Characteristics of the metallic bonds:

Free mobility of electrons contributes to:

1. High thermal and electrical conductivity.

2. Opacity (due to absorption of light by free electrons).

3. Metallic luster (free electrons re-emit light).

4. High ductility and malleability.

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 Ionic bonding Covalent bond Metallic bond
Metal + non-metal Non-metal + non-metal Metal + metal
Atoms release & atoms Atoms share electrons with Atoms release free electrons
receive electrons other atoms Attraction between +ve core
and electron cloud

Can conduct an electric Insulator Can conduct electricity and
current (in solution). heat.
Heat resistant Heat insulator High thermal conductivity
Low melting and boiling High melting point
point
BRITTLE (Easily break ) Depend on the state High ductility and
malleability

Water soluble Water insoluble Water insoluble
Insoluble in organic solvent soluble in organic solvent Insoluble in organic solvent

Examples Dental resin Metals
NaCL (dental amalgam, casting
Gypsum alloys, dental wrought
Phosphate cements wires)
DR/ FAHIEM M. EL-SHAMY
 Secondary
(Physical) bond

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 Secondary bonds don’t share electron.

 Arise from the polarization (charge variations) among molecules
or atomic groups i.e. formation of electrical dipoles.

Characteristics of secondary bonds:

 physical and weak

 Low melting point.

 High thermal expansion.

Mainly two types:

1- Hydrogen Bonding:
2- Van der Waals Forces
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 1. Hydrogen Bonding:
(Permanent dipole or polar forces):
✓ Occurs in asymmetric molecules->one atom attracts the
electrons→ becomes –ve pole.

✓ Other atom becomes +ve pole.

✓ Resulting in permanent dipole.

❑ H2O is an example:

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❑ H2O is an example:

The hydrogen bond is formed between

Oxygen (O) as electronegative atoms (electrons are more)

and Hydrogen (H) portion is positive.

 Stronger than van der Waals but weaker than covalent and ionic
bonds.

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 2. Van der Waals Forces:
 Normally, the electrons of the

atoms in inert gas are distributed
equally around the nucleus and
produce an electrostatic field
around the atom.

 However, this field may fluctuate

so that its charge becomes
momentarily positive and negative.

 A fluctuating dipole is thus

created that will attract other
similar dipoles. Such interatomic
forces are quite weak.
 Hydrogen Bonding Van der Waals Forces
Occurs in asymmetric molecules Occurs in symmetric molecules,
H2O is an example as inert gas

One atom attracts the electrons→ The electrostatic field around inert
becomes –ve gas atom →fluctuate → charge
Other atom becomes +ve. becomes momentarily positive and
negative.

Polarization : Permanent dipole or Polarization : fluctuating dipole
polar forces

weaker than covalent and ionic Quite weak
bonds.
Stronger than Vander Waal forces
 The structure of solids

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 The structure of solids
 In general, materials can be subdivided into two
categories according to their atomic arrangement.
crystalline & noncrystalline (amorphous).

Quartz

Salt

Diamond

Rubber Glass
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 Crystalline
 Their atoms are regularly arranged in a three-dimensional
periodic pattern known as space lattice.

 Have definite melting temperature.

Examples:
 Metals, Quartz, Diamond.
 Noncrystalline (Amorphous)
 Amorphous means without any form and no regular

arrangement of atoms.

 No definite melting temperature, gradually softens

on heating and gradually hardens on

cooling.(remember waxes are amorphous)

 Glass transition temperature Tg:

Is the temperature at which the amorphous structure

begins to change from solid to liquid state.

Examples :

✓ Gases , liquids and some solids like glass and some

polymer (waxes, rubber dental resins)
Crystalline Noncrystalline (Amorphous)
 Amorphous means without any form and
 Their atoms are regularly arranged
in a three-dimensional periodic no regular arrangement of atoms.
pattern known as space lattice.
 No definite melting temperature,
 Have definite melting temperature.
gradually softens on heating and
gradually hardens on cooling.(remember
waxes are amorphous)
 Glass transition temperature Tg:
Examples: Is the temperature at which the amorphous
 Metals : are crystalline. structure begins to change from solid to
liquid state.
Examples :
✓ Gases , liquids and some solids like glass
and some polymer (waxes, rubber dental
resins)

✓ Ceramics, such as porcelains, consists of Noncrystalline glass matrix and
crystalline inclusions.
✓ Composites have organic (a Noncrystalline) matrix and inorganic
(crystalline) filler particles.
Space lattice :
An arrangement of atoms in
space in which every atom is
situated similarly to every
other atom.
Space lattice
 It may the result of primary
or secondary bonds.
 Unit cell which is the smallest
repeating unit in the space
lattice.
Unit cell
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 There are 14 possible lattice types or forms.

Type of space lattice defined by

1. Length of the axes.
2. Angles between the edges.

Many of the metals used in dentistry belong to the cubic system.

Types of cubic system:
A, Simple cubic.
B, Body centered cubic.
C, Face centered cubic.
THANK YOU
33
 EVALUATION SHEET #2

1. Compare between the three types of primary bonds?

2. Compare between types of secondary bond?

3. Compare between crystalline and noncrystalline solids?

4. Draw and label the following: ionic bond, covalent bond,

and another ionic bond. Provide dental examples for

each.?