Week 6 Lec 3 Ch 4.ppt PDF

Summary

This document is a lecture presentation on imperfections in solids, including point defects, vacancy atoms, interstitial atoms, and substitutional atoms, and grain boundaries. It also explains that all crystalline solids contain vacancies and how the equilibrium number of vacancies increases exponentially with temperature. The importance of these imperfections and the use of alloys are mentioned.

Full Transcript

CH 4
IMPERFECTIONS IN
SOLIDS

Chapter 3 -
 Imperfections in Solids
There is no such thing as a perfect crystal.

What are these imperfections?
Why are they important?

Many of the important properties of
materials are due to the presence of
imperfections.

Chapter 3 - 2
 Types of Imperfections

Vacancy atoms
Interstitial atoms Point defects
Substitutional atoms

Dislocations Line defects

Grain Boundaries Area defects

Chapter 3 - 3
 Point Defects in Metals
Vacancies:
-vacant atomic sites in a structure.

The simplest of the point defects is a vacancy,
or vacant lattice site, one normally occupied
from which an atom is missing.

Vacancy
distortion
of planes

Chapter 3 - 4
 All crystalline solids contain
vacancies and, in fact, it is not
possible to create such a
material that is free of these
defects.

Chapter 3 - 5
 The equilibrium number of vacancies for a given quantity of
material depends on and increases with temperature
according to;

In this expression, N is the total number of
atomic sites, is the energy required for the
formation of a vacancy, T is the absolute
temperature1 in kelvins, and k is the gas or
Boltzmann’s constant.

Thus, the number of vacancies increases exponentially
with temperature; that is, as T in Equation 4.1
increases, so also does the expression exp (-Qv/kT)

Chapter 3 - 6
 Equilibrium Concentration:
Point Defects
Equilibrium concentration varies with temperature!
Activation energy, energy required
No. of defects for the formation of a vacancy
Nv  Q v 
Total No. of potential  exp  
N  kT  Temperature (K)
defect sites or atomic sites
Boltzmann's constant
-23
(1.38 x 10 J/atom-K)
-5
(8.62 x 10 eV/atom-K)
Each lattice site
is a potential
vacancy site
Chapter 3 - 7
Chapter 3 - 8
Chapter 3 - 9
 Self-Interstitials:

A self-interstitial is an atom from the crystal that is crowded into
an interstitial site, a small void space that under ordinary
circumstances is not occupied.

The formation of this defect is not highly probable, and it exists
in very small concentrations, which are significantly lower than
for vacancies.

-"extra" atoms positioned between atomic sites.

self-
interstitial
distortion
of planes

Chapter 3 - 10
 IMPURITIES IN SOLIDS
A pure metal consisting of only one type of atom just isn’t
possible; impurity or foreign atoms will always be present,
and some will exist as crystalline point defects.

In fact, even with relatively sophisticated techniques, it is
difficult to refine metals to a purity in excess of 99.9999%.
22 23
At this level, on the order of 10 to 10 to impurity atoms will be
present in one cubic meter of material.

Chapter 3 - 11
 IMPURITIES IN SOLIDS
ALLOY
Most familiar metals are not highly pure; rather, they are
alloys, in which impurity atoms have been added
intentionally to impart specific characteristics to the
material. Ordinarily, alloying is used in metals to improve
mechanical strength and corrosion resistance.

For example, sterling silver is a 92.5% silver – 7.5% copper
alloy. In normal ambient environments, pure silver is highly
corrosion resistant, but also very soft. Alloying with copper
significantly enhances the mechanical strength without
depreciating the corrosion resistance appreciably.

Chapter 3 - 12
Chapter 3 - 13
 Solid Solutions

A solid solution forms when, as the solute atoms are added
to the host material, the crystal structure is maintained,
and no new structures are formed.

It is useful to draw an analogy with a liquid solution. If two
liquids, soluble in each other (such as water and alcohol) are
combined, a liquid solution is produced as the molecules
intermix, and its composition is homogeneous throughout. A
solid solution is also compositionally homogeneous; the
impurity atoms are randomly and uniformly dispersed
within the solid.

Chapter 3 - 14
Impurity point defects are found in solid solutions, of
which there are two types: substitutional and
interstitial. For the substitutional type, solute or impurity
atoms replace or substitute for the host atoms

Chapter 3 - 15
 Imperfections in Metals (i)
Two outcomes if impurity (B) added to host (A):
Solid solution of B in A (i.e., random dist. of point defects)

OR

Substitutional solid soln. Interstitial solid soln.
(e.g., Cu in Ni) (e.g., C in Fe)
Solid solution of B in A plus particles of a new
phase (usually for a larger amount of B)
Second phase particle
-- different composition
-- often different structure.

Chapter 3 - 16
 Imperfections in Metals (ii)
Conditions for substitutional solid solution (S.S.)
W. Hume – Rothery rule
– 1. r (atomic radius) < 15%
– 2. Proximity in periodic table
i.e., similar electronegativities
– 3. Same crystal structure for pure metals
– 4. Valency
All else being equal, a metal will have a greater tendency
to dissolve a metal of higher valency than one of lower
valency

Chapter 3 - 17
 Imperfections in Metals (iii)
Application of Hume–Rothery rules – Solid
Solutions Element Atomic Crystal Electro- Valence
Radius Structure nega-
(nm) tivity
1. Check Cu and Ni Cu 0.1278 FCC 1.9 +2
C 0.071
H 0.046
O 0.060
Ag 0.1445 FCC 1.9 +1
Al 0.1431 FCC 1.5 +3
Co 0.1253 HCP 1.8 +2
Cr 0.1249 BCC 1.6 +3
Fe 0.1241 BCC 1.8 +2
Ni 0.1246 FCC 1.8 +2
Pd 0.1376 FCC 2.2 +2
Zn 0.1332 HCP 1.6 +2

Table on p. 118, Callister & Rethwisch 8e.

Chapter 3 - 18
 Composition
It is often necessary to express the composition (or
concentration) of an alloy in terms of its constituent
elements.

The two most common ways to specify composition
are weight (or mass) percent and atom percent.

The basis for weight percent (wt%) is the weight of a particular
element relative to the total alloy weight. For an alloy that
contains two hypothetical atoms denoted by 1 and 2, the
concentration of 1 in wt%, is defined as

Chapter 3 - 19
 Impurities in Solids
Specification of composition
m1
– weight percent C1  x 100
m1  m2
m1 = mass of component 1

' n m1
– atom percent C 
1 x 100
n m1  n m 2

nm1 = number of moles of component 1

Chapter 3 - 20
Chapter 3 - 21
Chapter 3 - 22
Simultaneous Substitutional and Interstitial Alloying
It's possible to have both substitutional and interstitial guest atoms coexisting in an
alloy. This occurs when:
Some guest atoms have a size similar to the host atoms and replace them at lattice
sites (substitutional).
Other guest atoms are much smaller and fit into the interstitial spaces (interstitial).
Examples of Alloys with Both Substitutional and Interstitial Guests:
1.Steel (Fe-C-X alloy):
1. Substitutional guest atoms: Elements like Cr, Ni, Mo, or Mn can substitute
for Fe atoms in the iron lattice.
2. Interstitial guest atoms: Carbon (C) occupies the interstitial spaces in the Fe
lattice.
2.Titanium Alloys (Ti-Al-O):
1. Substitutional guest atoms: Aluminum (Al) substitutes for titanium (Ti) in the
lattice.
2. Interstitial guest atoms: Oxygen (O), being smaller, occupies the interstitial
spaces in the Ti lattice.

Chapter 3 - 23
Applications: Advanced High-Strength Steels (AHSS): In
these steels, elements like manganese (Mn), silicon (Si), and
chromium (Cr) act as substitutional solutes, while carbon (C)
remains in the interstitial positions. This results in a strong,
ductile alloy.

Superalloys: Alloys used in jet engines often feature
substitutional alloying (e.g., with elements like Ni, Co, and
Cr) combined with interstitial alloying (e.g., with carbon,
nitrogen, or boron) to enhance mechanical properties at high
temperatures.

Chapter 3 - 24