Mechanical Properties (1) - DBM701 2024-2025 Dental Biomaterials PDF

Summary

These are notes on mechanical properties, for DBM701 Dental Biomaterials course, 2024-2025 academic year, by Professor Gihan Waly. The document details mechanical properties concepts, such as force, stress and strain, types of stresses, and stress-strain curves.

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DBM701- Dental Biomaterials (2024-2025)
Mechanical Properties (1) - Prof. Gihan Waly

Mechanical properties
Mechanical properties are a group of physical properties that describe the
behavior of materials under force or load. Mechanical properties of
orthodontic materials are important because these materials are subjected to
forces in service i.e. during fabrication or function. In general, the behaviour
of a solid under load is determined by the nature and/or strength of its
interatomic and intermolecular bonds.
1. Force:
Force is an action which, when applied to a body, produces or tends to
produce a change in the body’s position, movement and/or shape.
Characteristics of force: A force can be defined in terms of:
a. Magnitude: The units of force are Newton (N) or Pound (lb) where
1 lb = 4.4 N
b. Speed: According to its speed, force can be static or dynamic (Fig.1).

Figure (1): Static and dynamic forces.
c. Point of application:
When two forces applied on one body act on the same line, whether
directed towards each other or away from each other, this set of forces
gives a resultant normal force. On the other hand, when two forces
applied on one body act on two parallel lines (not on the same line),
whether directed towards or away from each other, this set of forces
gives a resultant tangential force (Fig. 2).

d. Direction:
When two forces, applied on one body, are acting on the same line and
directed away from each other, the resultant force is tensile while if the
two forces are directed towards each other, the resultant force is
compressive (Fig. 2).

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Mechanical Properties (1) - Prof. Gihan Waly

Figure (2): Effect of: (A) Point of application and (B) Direction of force

2. Stress:
Stress is defined as the internal reaction to an external force and is
equal in intensity and opposite in direction to the applied external force.
Both the applied force and the internal resistance are distributed over the
same given area of the body over which the force is applied. The stress (σ) is
calculated as the force per unit area.
force F
stress = or  =
area A
From the above equation, we see that the stress in a structure varies
directly with the external force and inversely with the area over which it is
applied. The most convenient way to measure the stress is to measure the
external force applied to the area, then calculate the stress from the previous
equation.
Units:
The units of stress are Pascal (Pa = N/m2), Megapascal (MPa =
2
1,000,000 Pa) and lb/in.
Types:
There are different types of stresses: (Fig. 3)
1. Normal or Axial:
 Tensile stress (t ),
 Compressive stress (c ),

2. Tangential:
 Shear stress ().

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Mechanical Properties (1) - Prof. Gihan Waly

Figure (3): Types of stresses

Tensile stress (t ):
Tensile stress is induced in a body loaded by tensile force i.e. two sets of
axial forces acting on the same line directed away from each other.
Molecules making up the body must resist being pulled apart.

Compressive stress (c ):
Compressive stress is induced in a body loaded by compressive force i.e.
two sets of axial forces acting on the same line directed towards each other.
Molecules making up the body must resist being forced more closely
together.

Shear stress ():
Shear is the result of two sets of forces being directed towards each other
or opposite each other but not on the same straight line i.e. parallel to each
other (such that the distance between them will be close to, but not equal to,
zero). Molecules of such a body must resist sliding past one another. e.g.
scissors are often called shears.

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Mechanical Properties (1) - Prof. Gihan Waly

Complex stresses
In reality, there is no pure tensile or pure compressive stress. When a
compressive force is applied to a body, compressive stress is generated
along the line of action of the force which tends to shorten the body.
Simultaneously, tensile stresses are generated in planes perpendicular to the
line of action of the force which tends to increase the cross sectional area of
the body. Shear stresses are also generated in some areas of the body as can
be seen in (Fig. 3)
N.B.: Under certain loading designs, other types of stresses are generated
like torsional stress and transverse stress.

3. Deformation and strain:
Deformation: is the distortion produced as a result of the stress induced
within the material. In case of axial stress, the deformation can be defined as
the change in length (Fig. 4). It is calculated as:

Figure (4): Deformation
Strain: is defined as the change in length per unit length and is calculated
as:
deformation
strain = or
original length

mm/mm or dimensionless

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Mechanical Properties (1) - Prof. Gihan Waly

Types of strain:
Each type of stress is capable of producing a corresponding type of
strain in the body e.g. tensile stress produces strain in the form of elongation
while compressive stress produces strain in the form of reduction in length
(shortening). Any type of those strains can be either elastic or plastic
(Fig. 5A&B). The differences between elastic and plastic strains can be
summarized in the following table:

Elastic strain Plastic strain
It is the strain that recovers upon It is the strain that does not recover
unloading. upon unloading and is therefore
permanent.
Associated with stretching but not Interatomic bonds are broken and
breakage of the chemical bonds new bonds are formed, thus atoms
between the atoms in the solid. change their neighbors.

Figure (5.A) : Mechanism of elastic
deformation (on atomic level)|

Figure (5.B): Mechanism of plastic
deformation (on atomic level)

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Mechanical Properties (1) - Prof. Gihan Waly

4. Stress-strain curve:
The relationship between stress and strain is often used to characterize
the mechanical properties of materials. Such data are generally obtained
using a mechanical testing machine which enables strain to be measured as a
function of stress and recorded automatically (Fig. 6).

Figure (6): Mechanical testing machine

One of the commonly used tests for evaluating the mechanical properties
of dental materials is the tensile test in which a rod sample of the material is
grabbed from its two ends then pulled to failure in a relatively short time at a
constant rate. The change in length is measured by an external extensometer
attached to the sample. The induced tensile stress (calculated by dividing
force over area) and the corresponding strain (calculated as change in length
per unit length) are plotted graphically with the stress represented on the
vertical axis and the strain plotted on the horizontal axis. Form the obtained
stress-strain curve (Fig. 7), several mechanical properties of the material can
be identified:

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Mechanical Properties (1) - Prof. Gihan Waly

Figure (7): stress-strain Curve

a. Proportional limit:
In the early (low strain) portion of the curve, many materials obey
Hooke’s law which states that “Up to a certain stress value, stress is
proportional to strain”. This means that up to this stress value, when the
stress is doubled, the strain is doubled and when the stress is tripled, the
strain is tripled and so on. As stress is gradually increased and once a
specific stress value called “proportional limit” is exceeded, many materials
eventually deviate from this linear proportionality.

Thus, the proportional limit can be defined as “the greatest stress the
material can withstand without deviation from Hooke’s law or from the
law of proportionality between stress and strain”.

b. Elastic limit:
If a relatively small tensile stress is induced in the rod specimen, the
specimen will return to its original length when the load is removed. If the
load is increased progressively in small increments and then released after
each increase in stress, a stress value will be reached at which the specimen
does not return to its original length when unloaded. At this point, the
material has been stressed beyond its elastic limit.
The elastic limit is defined as “the greatest stress to which a material can
be subjected such that it returns to its original dimensions when the force
is released” i.e. it is “the greatest stress the material can withstand without

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a resulting permanent deformation”. Therefore, the elastic limit describes
the elastic behaviour of the material.
For most materials, the proportional limit and the elastic limit represent
the same value, however, they differ in their fundamental concept.

c. Yield strength:
The yield strength lies on the stress-strain curve just after the elastic limit.
Once the elastic limit is exceeded, permanent strain occurs in the material.
Since it is often difficult to pinpoint the exact stress at which plastic
deformation begins, the yield strength is defined as “the stress at which a
limited specified amount of permanent strain has occurred in the
material”. The amount of permanent strain is arbitrarily selected, may be
0.1%, 0.2% or 0.5% of permanent strain. This selected amount of permanent
strain is referred to as percent offset. When comparing the strengths of two
materials, it is not correct to compare the yield strength at 0.5% offset for
one material with the yield strength at 0.1% offset for the other material. The
selected percent offset should be the same for both materials to ensure
standardization.
Clinical significance:
During construction of an appliance from a wire, the applied force should
induce a stress greater than the yield strength of the wire’s material to
allow permanent shaping.
During adjustment of a restoration, the applied force should induce a
stress greater than the yield strength of the material to produce permanent
deformation.
During function, the restoration should not be subjected to stresses above
the yield strength, otherwise, permanent deformation would occur and
the restoration will no more be fitting the purpose in spite of the fact that
it did not break. This is considered as a functional failure.

d. Ultimate strength and fracture strength:
If you carry on stressing the material beyond the yield strength, the
sample will eventually fracture (fail).
The ultimate strength is “the maximum stress the material can
withstand before fracture”. It can be ultimate tensile, compressive or shear
strength depending on the mode of loading. The ultimate strength of a
material can be determined by drawing a horizontal line from the highest
point on the stress-strain curve to the stress axis. The stress where this line

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intersects with the stress axis is called the ultimate strength. The ultimate
tensile strength is sometimes just called the tensile strength and the
ultimate compressive strength is also called the compressive strength.

The fracture strength is “the stress at which fracture of the material
occurs”.
After the maximum stress is reached, the material begins to elongate
excessively and the stress calculated from the force and original cross-
sectional area drops before final fracture occurs. The curve obtained by
calculations based on the original cross-sectional area is called “engineering
stress-strain curve”. If the decrease in the cross-sectional area of the
material is taken in consideration, the true stress-strain curve will be
obtained. In the true stress-strain curve, the facture strength would be higher
than in the engineering curve (Fig. 8). Although the true curve represents the
situation more accurately, the engineering curve is more commonly used.

Figure (8): (A): True versus engineering stress-strain curve.
(B): Localized reduction in cross-sectional area (necking)

e. Modulus of elasticity (Young’s Modulus) “E”:
The modulus of elasticity or Young’s modulus denoted by “E”, is the
constant of proportionality between stress and strain and represents the
slope of the elastic portion of the stress-strain curve. It can be calculated
from the following relation:


E= kg/cm2 or MPa or lb/in2


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The modulus of elasticity represents the stiffness of the material within
the elastic range. Materials with high modulus are called “rigid” or
“stiff” while those of low modulus are described as “flexible”.
The modulus of elasticity of a material does not change either tested
under compression or tension (Fig. 9).

Figure (9): Same slope of the elastic part of both S-S curves of one material tested under
tension and compression.
The elastic modulus depends on the interatomic or intermolecular forces
of the material. The stronger the basic attraction forces, the more difficult
is the stretching of bonds, thus, the greater is the value of the modulus of
elasticity.
Materials such as rubbers and plastics have low values for the modulus of
elasticity and are readily deformed elastically, whereas many metals and
alloys have much higher values. Representative values of the modulus of
elasticity of some materials are shown in the following table:

Material Elastic modulus (GPa)
Stainless steel 179
Cobalt-chromium-nickel 184
Ni-Ti 41
Beta-titanium 72
Enamel 84.1
Dentin 18.3
Composite resin 16.6

Clinical significance:
1. Materials with high modulus of elasticity allow an even stress
distribution over the area to which the load is applied. This is an
important feature in denture base materials. Denture materials with high
modulus of elasticity can be used in thinner section without fear of
uneven stress distribution.

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2. Bridges, particularly long span bridges, should be fabricated from a
material that has high modulus of elasticity to allow even stress
distribution, and to avoid bending.

3. The stiffness of the orthodontic wire determines its ability to deliver a
suitable force that allows tooth movement during orthodontic treatment.
Stiff wires (like stainless steel) can deliver higher forces that allow a
more rapid tooth movement, while more flexible wires (like Ni-Ti) apply
smaller forces which bring about slower tooth movements.

f. Flexibility:
The maximal flexibility is defined as “the strain that occurs when the
material is stressed to its proportional limit” (Fig. 10).

Figure (10): Maximum flexibility

It is computed from the following relation:

Where, εm = maximum flexibility
PL = proportional limit
E = modulus of elasticity

Clinical significance:
The maximum flexibility of impression materials should be high to allow
removal of the impression materials from sever undercuts without plastic
deformation.

Orthodontic wires should have high maximum flexibility to allow the
wire to undergo large deflections without permanent deformation. A

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closely related term commonly used by orthodontists to describe this
property is the “springback potential”. The springback potential is
calculated as the ratio between yield strength and modulus of elasticity. It
is an indication of the springness of the wire.

g. Brittleness:
If a material demonstrates no or very little plastic deformation on
load application, it is described as being brittle. Thus, a brittle material
fractures at or very near its proportional limit (Fig. 14A). This fracture
occurs by crack propagation and the fracture surface is characterized by
granules (Fig. 15A).
In general, brittle materials are weaker in tension than in compression. This
is attributed to the fact that brittle materials inherently contain flaws or
cracks. When subjected to tensile loading, the resultant tensile stresses tend
to further open these cracks leading to crack propagation. On the other hand,
when a brittle material is subjected to compressive loading, the generated
compressive stress tends to close the cracks (Fig. 11). Examples of brittle
materials used in dentistry are dental amalgam, dental ceramics and dental
cements.
N.B.: A brittle material does not necessarily lack strength e.g. several
ceramics have high strength but are still brittle.

Figure (11): Compression tends to close cracks while tension tends to open them further

h. Malleability and ductility:
These are properties of metals and alloys. They indicate the workability of
the metal or alloy.
The malleability of a material is its ability to be hammered into thin
sheets without fracturing i.e. to be plastically deformed under compressive
force (Fig. 12). It is related to the burnishability of the material.

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Figure (12): Malleable material hammered into sheets

On the other hand, the ductility of the material is its ability to be drawn
into wires without fracture i.e. to be plastically deformed under tensile force
(Fig. 13).

Figure (13): Ductile material drawn into wires
Fracture of ductile materials when subjected to tensile loading is preceded
by localized reduction in cross-sectional area at the fracture site, a
phenomenon called “necking” (Fig. 14B & 15B).

i. Percent elongation:
The deformation that results from the application of a tensile force is
elongation. The ability of an alloy to permanently elongate under tensile
loading gives an indication of the workability of such alloy. The percent
elongation represents the maximum amount of permanent deformation a
material can exhibit and it can be calculated as:
% Elongation = (increase in length / original length) x 100

N.B.: In this equation, the increase in length is measured at the point of
fracture.
A material, like many dental gold alloys, that exhibits a 20% total
elongation at the time of fracture has increased one fifth of its length. Such
alloys are described to be ductile, whereas, a material with only 1%
elongation would be considered brittle e.g. Nickel-chromium alloy.

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Comparison between brittle and ductile materials
Brittle material Ductile material
Exhibits no or little plastic Exhibits a large amount of plastic
deformation i.e. fractures at or near deformation
the proportional limit
Has low % elongation Has high % elongation

Figure (14A): Stress-strain curve of a brittle Figure (14B): Stress-strain curve of a
material ductile material
Fractures by crack propagation Fractures by necking

Figure (15A): Fracture of a brittle material Figure (15B): Fracture of a ductile
material
Brittle fracture requires energy to Ductile fracture requires not only
separate atoms and to expose new the energy to separate atoms, but
surfaces along the fracture path. much additional energy to deform
the material plastically before
fracture.
Examples: Dental amalgam, cements Examples: Most metals and alloys
and ceramics

j. Resilience:
Resilience represents “the amount of energy needed to deform the
material to its proportional limit”. It is represented by the area under the
straight portion of the stress-strain curve i.e. the area of the shaded triangle
in (Fig. 16).

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Figure (16): The area under the straight part of the stress-strain curve representing
resilience

Resilience is also called the stored energy because when the material is
stressed to its proportional limit, the absorbed energy remains stored in the
material as long as it is loaded. Once the load is removed, this energy is
released causing complete recovery of the elastically deformed material.
Clinical significance:
Resilience is an important requirement of orthodontic wires because
when the wire is elastically bent, its stored energy can be released over the
required time to move teeth gradually. The greater the resilience of the wire,
the more the energy it can temporarily store then release during the
orthodontic treatment.

l. Toughness:
Toughness represents “the energy required to stress the material to the
point of fracture”. It is represented by the area under both the elastic and
plastic portions of the stress-strain curve (Fig. 17). The toughest materials
are those with high proportional limit and good ductility. Thus, brittle
materials tend to be not tough.

Figure (17): The area under both elastic and plastic parts of the stress-strain curve
represents toughness

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Fracture Toughness
When cracks are present in a material, less force is needed to cause
fracture because the stresses tend to be intensified at the cracks’ tips. This
phenomenon is called “stress concentration”. This is especially true with
brittle materials (like ceramics) while with ductile materials (like metals),
cracks are not as dangerous.
The resistance of the material to catastrophic propagation of cracks and
flaws under an induced stress is called fracture toughness. Accordingly,
brittle materials have low fracture toughness while ductile materials have
high fracture toughness.
A commonly used strengthening mechanism is to incorporate fillers into
the material. The fillers deflect the crack or absorbs its energy, thus, more
energy will be needed to propagate the crack leading to higher fracture
toughness.

Interpretation of the stress-strain curve:
Several properties of the material can be determined from its stress-strain
curve:
The slope of the elastic part of the curve determines whether the material
is stiff or flexible. A material with a high slope is described as stiff and
that with low slope is flexible.
The value of the proportional limit determines whether the material is
weak or strong.
The amount of plastic deformation (i.e. the length of the plastic part of
the curve) determines whether the material is brittle or (ductile or
malleable)
The area under the elastic part of the curve determines whether the
material is resilient or not.
The area under both elastic and plastic parts of the curve determines
whether the material is tough or not (Fig. 18).

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Figure (18) Stress-strain curves for materials with various combinations of properties

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