1 Essentials of Materials Science and Engineering, Donald R. Askeland, SI ed.課本 HOMEWORK (4E 第四版) CH.1 #3,10,12,15,21,29,32,34. 1-3 Define the following terms: (a) composition; (b) structure; (c) synthesis; (d) processing; and (e) microstructure. 1-10 For each of the following classes of materials, give two specific examples that are a regular part of your life: (a) metals; (b) ceramics; (c) polymers; and (d) semiconductors. Specify the object that each material is found in and explain why the material is used in each specific application. Hint: One example answer for part (a) would be that aluminum is a metal used in the base of some pots and pans for even heat distribution. It is also a lightweight metal that makes it useful in kitchen cookware. Note that in this partial answer to part (a), a specific metal is described for a specific application. 1-12 Describe the enabling materials property of each of the following and why it is so: (a) aluminum for airplane bodies; (b) polyurethane for teeth aligners (invisible braces); (c) steel for the ball bearings in a bicycle’s wheel hub; (d) polyethylene terephthalate for water bottles; and (e) glass for wine bottles. 1-21 Steel is often coated with a thin layer of zinc if it is to be used outside. What characteristics do you think the zinc provides to this coated, or galvanized, steel? What precautions should be considered in producing this product? How will the recyclability of the product be affected?
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Essentials of Materials Science and Engineering, Donald R.
Askeland, SI ed. HOMEWORK (4E ) CH.1 #3,10,12,15,21,29,32,34.
1-3 Define the following terms:
(a) composition;
(b) structure;
(c) synthesis;
(e) microstructure.
1-10 For each of the following classes of materials, give two
specific examples that are a
regular part of your life:
(a) metals;
(b) ceramics;
(d) semiconductors.
Specify the object that each material is found in and explain why
the material is used in
each specific application. Hint: One example answer for part (a)
would be that aluminum is a
metal used in the base of some pots and pans for even heat
distribution. It is also a
lightweight metal that makes it useful in kitchen cookware. Note
that in this partial answer
to part (a), a specific metal is described for a specific
application.
1-12 Describe the enabling materials property of each of the
following and why it is
so: (a) aluminum for airplane bodies; (b) polyurethane for teeth
aligners (invisible braces); (c) steel for the ball bearings in a
bicycle’s wheel hub; (d) polyethylene terephthalate for water
bottles; and (e) glass for wine bottles.
1-21 Steel is often coated with a thin layer of zinc if it is to be
used outside. What
characteristics do you think the zinc provides to this coated, or
galvanized, steel? What
precautions should be considered in producing this product? How
will the recyclability of the
product be affected?
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1-29 What properties should the head of a carpenter’s hammer
possess? How would you
manufacture a hammer head?
1-32 You would like to be able to identify different materials
without resorting to chemical
analysis or lengthy testing procedures. Describe some possible
testing and sorting
techniques you might be able to use based on the physical
properties of materials.
1-34 Some pistons for automobile engines might be produced from a
composite material
containing small, hard silicon carbide particles in an aluminum
alloy matrix. Explain what
benefits each material in the composite may provide to the overall
part. What problems
might the different properties of the two materials cause in
producing the part?
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CH.2 #17,19,21,33,45,47.
2-17 Plot the melting temperatures of elements in the 4A to 8–10
columns of the periodic
table versus atomic number (i.e., plot melting temperatures of Ti
through Ni, Zr through Pd,
and Hf through Pt). Discuss these relationships, based on atomic
bonding and binding
energies: (a) as the atomic number increases in each row of the
periodic table and (b) as the
atomic number increases in each column of the periodic table.
2-19 Compare and contrast metallic and covalent primary bonds in
terms of (a) the nature
of the bond, (b) the valence of the atoms involved, and (c) the
ductility of the materials
bonded in these ways.
2-45 Steel is coated with a thin layer of ceramic to help protect
against corrosion. What do
you expect to happen to the coating when the temperature of the
steel is increased
significantly? Explain.
2-48 Name at least four allotropes of carbon. Why is graphite
electrically conductive while
diamond is not if both are pure forms of carbon?
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9
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CH.3 #1,2,9,11,16,17,39,51,52,54,55,98,99,101.
3-11 Define the terms lattice, unit cell, basis, and crystal
structure.
3-14 Calculate the atomic radius in cm for the following: (a) BCC
metal with a0 = 0.3294 nm;
and (b) FCC metal with a0 = 4.0862 A.
3-39 Above 882°C, titanium has a BCC crystal structure, with a =
0.332 nm. Below this
temperature, titanium has an HCP structure, with a = 0.29503 nm and
c = 0.46831 nm.
Determine the percent volume change when BCC titanium transforms to
HCP titanium. Is
this a contraction or expansion?
3-51 Determine the Miller indices for the directions in the cubic
unit cell shown in Figure 3-
37.
3-54 Determine the indices for the planes in the cubic unit cell
shown in Figure 3-39.
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3-98 Figure 3-45 shows the results of an x-ray diffraction
experiment in the form of the
intensity of the diffracted peak versus the 2θ diffraction angle.
If x-rays with a wavelength
of 0.15418 nm are used, determine (a) the crystal structure of the
metal; (b) the indices of
the planes that produce each of the peaks; and (c) the lattice
parameter of the metal.
3-99 Figure 3–46 shows the results of an x-ray diffraction
experiment in the form of the
intensity of the diffracted peak versus the 2θ diffraction angle.
If x-rays with a wavelength
of 0.07107 nm are used, determine (a) the crystal structure of the
metal; (b) the indices of
the planes that produce each of the peaks; and (c) the lattice
parameter of the metal.
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13
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CH.4 #16,21,24,30,33,51,65,66,73.
4-16 Suppose one Schottky defect is present in every tenth unit
cell of MgO. MgO has the
sodium chloride crystal structure and a lattice parameter of 0.396
nm. Calculate (a) the
number of anion vacancies per cm3; and (b) the density of the
ceramic.
4-21 What is the Burger’s vector orientation relationship with the
dislocation axis for both
edge and screw dislocations?
4-24 What are the Miller indices of the slip directions:
(a) on the (111) plane in an FCC unit cell?
(b) on the (011) plane in a BCC unit cell?
4-30 The crystal shown in Figure 4-19 contains two dislocations A
and B. If a shear stress is
applied to the crystal as shown, what will happen to dislocations A
and B?
4-51 A copper-zinc alloy has the properties shown in the table
below:
Determine (a) the constants in the Hall-Petch equation; and (b) the
grain size required
to obtain a strength of 200 MPa.
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CH 6 #4,13,38,42,47,61,66,76.
6-38 The following data were collected from a standard 12.83
mm-diameter test specimen
of a copper alloy (o = 50.8 mm):
After fracture, the total length was 76.556 and the diameter was
9.5 mm. Plot the
engineering stress strain curve and calculate (a) the 0.2% offset
yield strength; (b) the tensile
strength; (c) the modulus of elasticity; (d) the % elongation; (e)
the % reduction in area; (f)
the engineering stress at fracture; and (g) the true stress at
necking; and (h) the modulus of
resilience.
6-42 Consider the tensile stress strain diagram in Figure 6–30
labeled 1 and 2. These
diagrams are typical of metals. Answer the following questions, and
consider each part as a
separate question that has no relationship to previous parts of the
question.
(a) Samples 1 and 2 are identical except for the grain size. Which
sample has the smaller
grains? How do you know?
(b) Samples 1 and 2 are identical except that they were tested at
different temperatures.
Which was tested at the lower temperature? How do you know?
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(c) Samples 1 and 2 are different materials. Which sample is
tougher? Explain.
(d) Samples 1 and 2 are identical except that one of them is a pure
metal and the other has a
small percentage alloying addition. Which sample has been alloyed?
How do you
know?
(e) Given the stress strain curves for materials 1 and 2, which
material has the lower
hardness value on the Brinell hardness scale? How do you
know?
(f) Are the stress strain curves shown true stress strain or
engineering stress strain curves?
How do you know?
(g) Which of the two materials represented by samples 1 and 2 would
exhibit a higher shear
yield strength? How do you know?
6-47 A three-point bend test is performed on a block of ZrO2 that
is 203.2 mm long, 12.7 mm
wide, and 6.35 mm thick and is resting on two supports 101.6 mm
apart. When a force of
1780 N is applied, the specimen deflects 0.94 mm and breaks.
Calculate (a) the flexural
strength; and (b) the flexural modulus, assuming that no plastic
deformation occurs.
6-61 The elastic modulus of a metallic glass is determined to be 95
GPa using
nanoindentation testing with a diamond Berkovich tip. The Poisson’s
ratio of the metallic
glass is 0.36. The unloading stiffness as determined from the
load-displacement data is 5.4
× 105 N/m. The maximum load is 120 mN. What is the hardness of the
metallic glass at this
indentation depth?
6-66 The following data were obtained from a series of Charpy
impact tests performed on
four ductile cast irons, each having a different silicon content.
Plot the data and determine (a)
the transition temperature of each (defined by the mean of the
absorbed energies in the
ductile and brittle regions); and (b) the transition temperature of
each (defined as the
temperature that provides 10 J absorbed energy). (c) Plot the
transition temperature versus
silicon content and discuss the effect of silicon on the toughness
of the cast iron. What is the
maximum silicon allowed in the cast iron if a part is to be used at
25oC?
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6-76 A load versus displacement diagram is shown in Figure 6–31 for
a metallic glass. A
metallic glass is a non-crystalline (amorphous) metal. The sample
was tested in compression.
Therefore, even though the load and displacement values are plotted
as positive, the sample
length was shortened during the test. The sample had a length in
the direction of loading of
6 mm and a cross-sectional area of 4 mm2. Numerical values for the
load and displacement
are given at the points marked with a circle and an X. The first
data point is (0, 0). Sample
failure is indicated with an X. Answer the following
questions.
a. Calculate the elastic modulus.
b. How does the elastic modulus compare to the modulus of
steel?
c. Calculate the engineering stress at the proportional
limit.
d. Consider your answer to part (c) to be the yield strength of the
material. Is this a
high yield stress or a low yield stress? Support your answer with
an order of
magnitude comparison for a typical polycrystalline metal.
e. Calculate the true strain at the proportional limit. Remember
that the length of
the sample is decreasing in compression.
f. Calculate the total true strain at failure.
g. Calculate the work of fracture for this metallic glass based on
engineering stress
and strain.
CH 7 #1,19,23,32,44,48,49.
7-1 Alumina (Al2O3) is a brittle ceramic with low toughness.
Suppose that fibers of silicon
carbide SiC, another brittle ceramic with low toughness, could be
embedded within the
alumina. Would doing this affect the toughness of the ceramic
matrix composite? Explain.
7-32 A cyclical load of 6.67 kN is to be exerted at the end of a
254 mm-long aluminum beam
(Figure 7–18). The bar must survive for at least 106 cycles. What
is the minimum diameter of
the bar?
13-5 Estimate the AISI-SAE number for steels having the following
microstructures.
(a) 38% pearlite–62% primary ferrite;
(b) 93% pearlite–7% primary cementite;
(c) 97% ferrite–3% cementite; and
(d) 86% ferrite–14% cementite.
13-10 Complete the following table:
13-14 Describe the microstructure present in a 1050 steel after
each step in the following
heat treatments:
(a) heat at 820°C, quench to 650°C and hold for 90 s, and quench to
25°C;
(b) heat at 820°C, quench to 450°C and hold for 90 s, and quench to
25°C;
(c) heat at 820°C and quench to 25°C;
(d) heat at 820°C, quench to 720°C and hold for 100 s, and quench
to 25°C;
(e) heat at 820°C, quench to 720°C and hold for 100 s, quench to
400°C and hold for 500 s,
and quench to 25°C;
(f) heat at 820°C, quench to 720°C and hold for 100 s, quench to
400°C and hold for 10
s, and quench to 25°C; and
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(g) heat at 820°C, quench to 25°C, heat to 500°C and hold for 103
s, and air cool to 25°C.
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