Chapter 9

Question 1

Argon oxygen decarburization (AOD)

Answer 1

A process to refine stainless steel. The carbon dissolved

in molten stainless steel is reduced by blowing argon gas mixed with oxygen.

Question 2

Brazing

Answer 2

An alloy, known as a filler, is used to join two materials to one another. The composition of
the filler, which has a melting temperature above 450°C, is quite different from the metal being joined.

Question 3

Cavities

Answer 3

Small holes present in a casting.

Question 4

Cavity shrinkage

Answer 4

A large void within a casting caused by the volume contraction that occurs
during solidification

Question 5

Chill zone

Answer 5

A region of small, randomly oriented grains that forms at the surface of a casting as a
result of heterogeneous nucleation.

Question 6

Chvorinov’s rule

Answer 6

The solidification time of a casting is directly proportional to the square of the
volume-to-surface area ratio of the casting

Question 7

Columnar zone

Answer 7

A region of elongated grains having a preferred orientation that forms as a result
of competitive growth during the solidification of a casting.

Question 8

Continuous casting

Answer 8

A process to convert molten metal or an alloy into a semi-finished product
such as a slab.

Question 9

Critical radius (r*)

Answer 9

The minimum size that must be formed by atoms clustering together in the
liquid before the solid particle is stable and begins to grow

Question 10

Dendrite

Answer 10

The treelike structure of the solid that grows when an undercooled liquid solidifies

Question 11

Directional solidification (DS

Answer 11

A solidification technique in which cooling in a given direction
leads to preferential growth of grains in the opposite direction, leading to an anisotropic and an oriented
microstructure.

Question 12

Dispersion strengthening

Answer 12

Increase in strength of a metallic material by generating resistance
to dislocation motion by the introduction of small clusters of a second material. (Also called second-
phase strengthening.)

Question 13

Embryo

Answer 13

A particle of solid that forms from the liquid as atoms cluster together. The embryo may
grow into a stable nucleus or redissolve.

Question 14

Epitaxial growth

Answer 14

Growth of a single-crystal thin film on a crystallographically matched singlecrystal
substrate.

Question 15

Equiaxed zone

Answer 15

A region of randomly oriented grains in the center of a casting produced as a
result of widespread nucleation.

Question 16

Fusion welding

Answer 16

Joining process in which a portion of the materials must melt in order to achieve
good bonding.

Question 17

Fusion zone

Answer 17

The portion of a weld heated to produce all liquid during the welding process.
Solidification of the fusion zone provides joining

Question 18

Gas flushing

Answer 18

A process in which a stream of gas is injected into a molten metal in order to eliminate
a dissolved gas that might produce porosity.

Question 19

Gas porosity

Answer 19

Bubbles of gas trapped within a casting during solidification, caused by the lower
solubility of the gas in the solid compared with that in the liquid.

Question 20

Glass-ceramics

Answer 20

Polycrystalline, ultra-fine grained ceramic materials obtained by controlled crystallization
of amorphous glasses.

Question 21

Grain refinement

Answer 21

The addition of heterogeneous nuclei in a controlled manner to increase the
number of grains in a casting.

Question 22

Growth

Answer 22

The physical process by which a new phase increases in size. In the case of solidification,
this refers to the formation of a stable solid as the liquid freezes.

Question 23

Heterogeneous nucleation

Answer 23

Formation of critically-sized solid from the liquid on an impurity
surface.

Question 24

Homogeneous nucleation

Answer 24

Formation of critically sized solid from the liquid by the clustering
together of a large number of atoms at a high undercooling (without an external interface).

Question 25

Ingot

Answer 25

A simple casting that is usually remelted or reprocessed by another user to produce a more
useful shape.

Question 26

Ingot casting

Answer 26

Solidification of molten metal in a mold of simple shape. The metal then requires
extensive plastic deformation to create a finished product.

Question 27

Ingot structure

Answer 27

The macrostructure of a casting, including the chill zone, columnar zone, and
equiaxed zone.

Question 28

Inoculants

Answer 28

Materials that provide heterogeneous nucleation sites during the solidification of a
material.

Question 29

Inoculation

Answer 29

The addition of heterogeneous nuclei in a controlled manner to increase the number
of grains in a casting.

Question 30

Interdendritic shrinkage

Answer 30

Small pores between the dendrite arms formed by the shrinkage that
accompanies solidification. Also known as microshrinkage or shrinkage porosity.

Question 31

Investment casting

Answer 31

A casting process that is used for making complex shapes such as turbine
blades, also known as the lost wax process

Question 32

Lamellar

Answer 32

A plate-like arrangement of crystals within a material

Question 33

Latent heat of fusion ((delta)Hf)

Answer 33

The heat evolved when a liquid solidifies. The latent heat of fusion
is related to the energy difference between the solid and the liquid.

Question 34

Local solidification time

Answer 34

The time required for a particular location in a casting to solidify once
nucleation has begun.

Question 35

Lost foam process

Answer 35

A process in which a polymer foam is used as a pattern to produce a casting.

Question 36

Lost wax process

Answer 36

A process in which a wax pattern is used to cast a metal

Question 37

Microshrinkage

Answer 37

Small, frequently isolated pores between the dendrite arms formed by the shrinkage
that accompanies solidification. Also known as microshrinkage or shrinkage porosity

Question 38

Mold constant (B)

Answer 38

A characteristic constant in Chvorinov’s rule.

Question 39

Mushy-forming alloys

Answer 39

Alloys with a cast macrostructure consisting predominantly of equiaxed
grains. They are known as such since the cast material seems like a mush of solid grains floating in
a liquid melt.

Question 40

Nucleation

Answer 40

The physical process by which a new phase is produced in a material. In the case of
solidification, this refers to the formation of small, stable solid particles in the liquid.

Question 41

Nuclei

Answer 41

Small particles of solid that form from the liquid as atoms cluster together. Because
these particles are large enough to be stable, growth of the solid can begin.

Question 42

Permanent mold casting

Answer 42

A casting process in which a mold can be used many times.

Question 43

Photochromic glass

Answer 43

Glass that changes color or tint upon exposure to sunlight

Question 44

Pipe shrinkage

Answer 44

A large conical-shaped void at the surface of a casting caused by the volume
contraction that occurs during solidification.

Question 45

Planar growth

Answer 45

The growth of a smooth solid-liquid interface during solidification when no
undercooling of the liquid is present.

Question 46

Preform

Answer 46

A component from which a fiber is drawn or a bottle is made.

Question 47

Pressure die casting

Answer 47

A casting process in which molten metal is forced into a die under
pressure.

Question 48

Primary processing

Answer 48

Process involving casting of molten metals into ingots or semi-finished useful
shapes such as slabs.

Question 49

Rapid solidification processing

Answer 49

Producing unique material structures by promoting unusually

high cooling rates during solidification.

Question 50

Recalescence

Answer 50

The increase in temperature of an undercooled liquid metal as a result of the liberation
of heat during nucleation.

Question 51

Riser

Answer 51

An extra reservoir of liquid metal connected to a casting. If the riser freezes after the casting,
the riser can provide liquid metal to compensate for shrinkage.

Question 52

Sand casting

Answer 52

A casting process using sand molds

Question 53

Secondary dendrite arm spacing (SDAS)

Answer 53

The distance between the centers of two adjacent

secondary dendrite arms.

Question 54

Secondary processing

Answer 54

Processes such as rolling, extrusion, etc. used to process ingots or slabs
and other semi-finished shapes.

Question 55

Shrinkage

Answer 55

Contraction of a casting during solidification.

Question 56

Shrinkage porosity

Answer 56

Small pores between the dendrite arms formed by the shrinkage that accompanies
solidification. Also known as microshrinkage or interdendritic porosity.

Question 57

Sievert’s law

Answer 57

The amount of a gas that dissolves in a metal is proportional to the square root of
the partial pressure of the gas in the surroundings.

Question 58

Skin-forming alloys

Answer 58

Alloys whose microstructure shows an outer skin of small grains in the chill
zone followed by dendrites.

Question 59

Soldering

Answer 59

Soldering is a joining process in which the filler has a melting temperature below 450°C;
no melting of the base materials occurs

Question 60

Solidification front

Answer 60

Interface between a solid and liquid

Question 61

Solidification process

Answer 61

Processing of materials involving solidification (e.g., single crystal growth,
continuous casting, etc.).

Question 62

Solid-state phase transformation

Answer 62

A change in phase that occurs in the solid state

Question 63

Specific heat

Answer 63

The heat required to change the temperature of a unit weight of the material one degree

Question 64

Spherulites

Answer 64

Spherical-shaped crystals produced when certain polymers solidify

Question 65

Stainless steel

Answer 65

A corrosion resistant alloy made from Fe-Cr-Ni-C.

Question 66

Superheat

Answer 66

The difference between the pouring temperature and the freezing temperature

Question 67

Thermal arrest

Answer 67

A plateau on the cooling curve during the solidification of a material caused by
the evolution of the latent heat of fusion during solidification. This heat generation balances the heat
being lost as a result of cooling.

Question 68

Total solidification time

Answer 68

The time required for the casting to solidify completely after the casting
has been poured.

Question 69

Undercooling

Answer 69

The temperature to which the liquid metal must cool below the equilibrium freezing
temperature before nucleation occurs

Question 70

Supercooling is considered (eutectic, eutectoid or peritectic))

Answer 70

eutectic, eutectoid)

Question 71

superheating is(eutectic, eutectoid or peritectic))

Answer 71

peritectic

Question 72

T / F Small supercooling - slow nucleation rate

Answer 72

True

Question 73

T / F Small supercooling - many nuclei

Answer 73

False

Question 74

T / F Small supercooling - large crystals

Answer 74

True

Question 75

T / F Large supercooling - rapid nucleation rate

Answer 75

True

Question 76

T / F Large supercooling - many nuclei

Answer 76

True

Question 77

T / F Large supercooling - small crystals

Answer 77

True

Question 78

Strain free grains nucleate a prior Cold Worked grain boundaries is known as

Answer 78

Recrystallization

Question 79

Grain Size Strengthening takes Take advantage of heterogeneous or homogenous nucleation?

Answer 79

heterogeneous nucleation

Question 80

__________ plays a critical role in the processing of

metals, alloys, thermoplastics and inorganic glasses

Answer 80

Solidification

Question 81

______ produces a critical-size solid particle from

the liquid melt.

Answer 81

Nucleation

Question 82

________ nucleation requires large undercooling

of the liquid and is not commonly observed.

Answer 82

Homogeneous

Question 83

________ nucleation is always favored andallows a mechanism for generating fine grain sizes.

Answer 83

Heterogeneous

Question 84

Control of the cooling process allows the generation

of desired internal _____ ________

Answer 84

grain structure

Question 85

Do you know your cooling curves?

Answer 85

YES!