EDS 03 Minerals

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3

Minerals

We live in a world of minerals—they are everywhere around us. Gems and jewelry are
minerals. Gravel and sand are minerals. Mud is a mixture of microscopic minerals. Ice is a
mineral, and even dust in the air we breathe is made up of tiny mineral grains. Minerals
sustain our lives and provide continuously for society. The houses in which we live, the automobiles we drive, as well as the roads and other structures of our society, and almost
everything we touch are made of minerals or material derived from minerals. Indeed, on
average, every person on Earth uses, directly or indirectly, 10 metric tons of minerals each
year.
But the importance of minerals extends far beyond their value as economic deposits.
Minerals are also the substance of Earth’s natural systems. The green and white crystals in
this beautiful photograph are two very different minerals. The lustrous pastel green crystals
are apophyllite and the sparkling white needles are mesolite. Each mineral has distinguishing properties. Every one of the tiny ice-clear crystals in these radial sprays of mesolite has
much in common with all of the other grains of its mineral species. For example, all grains
of mesolite have the same internal arrangement of atoms and have the same chemical and
physical properties even though individuals may vary greatly in size and shape. The atomic

52

structure of mesolite creates a natural chemical sieve. Its open structure allows some molecules and ions dissolved in water to move through the framework of the atoms, but it will
filter out the larger molecules. Mesolite’s internal structure contains chains of atomic tetrahedrons aligned in one direction; this produces the needle-like shape of the crystals. The
mineral breaks preferentially between the long chains where atomic bonds are weakest.
All of Earth’s dynamic processes involve the growth and destruction of minerals as
matter changes from one state to another. As Earth’s surface weathers and erodes, some
minerals are destroyed and others grow in their place. Mesolite and apophyllite in this photo
grew from a watery solution as flowed through ancient lava flows. As sediments accumulate
in the oceans, minerals also grow from solution. Other minerals grow from molten rock when
lava erupts from volcanoes and cools. Deep below Earth’s surface, high pressure and temperature remove atoms from the crystal structures of some minerals and cause them to recombine them into new minerals. As tectonic plates move and continents drift, minerals are created and destroyed by a variety of processes. Some knowledge of Earth’s major minerals,
therefore, is essential to understanding Earth’s dynamics.
In this chapter, we survey the general characteristics of minerals and the physical properties that identify them. We then explore the major rock-forming minerals in preparation
for a study of the major rock types in Chapters 4, 5, and 6.

Photograph by Chip Clark.

53

MAJOR CONCEPTS
1. An atom is the smallest unit of an element that possesses the properties of
2.
3.
4.
5.
6.
7.
8.

9.

the element. It consists of a nucleus of protons and neutrons and a surrounding cloud of electrons.
An atom of a given element is distinguished by the number of protons in its
nucleus. Isotopes are varieties of an element, distinguished by the different
numbers of neutrons in their nuclei.
Ions are electrically charged atoms, produced by a gain or loss of electrons.
Matter exists in three states: (a) solid, (b) liquid, and (c) gas. The differences among the three are related to the degree of ordering of the atoms.
A mineral is a natural solid possessing a specific internal atomic structure and
a chemical composition that varies only within certain limits. Each type of
mineral is stable only under specific conditions of temperature and pressure.
Minerals grow when atoms are added to the crystal structure as matter
changes from the gaseous or the liquid state to the solid state. Minerals dissolve or melt when atoms are removed from the crystal structure.
All specimens of a mineral have well-defined physical and chemical properties (such as crystal structure, cleavage or fracture, hardness, and density).
Silicate minerals are the most important minerals and form more than 95%
of Earth’s crust.The most important silicates are feldspars, micas, olivines, pyroxenes, amphiboles, quartz, and clay minerals. Important nonsilicate minerals
are calcite, dolomite, gypsum, and halite.
Minerals grow and are broken down under specific conditions of temperature, pressure, and chemical composition. Consequently, minerals are a record
of the changes that have occurred in Earth throughout its history.

MATTER
An atom is the smallest unit of an element that possesses the properties of
the element. It consists of a nucleus of protons and neutrons and a surrounding cloud of electrons. There are three states of matter: gas, liquid,
and solid. Each state is distinguished by unique physical properties.
Processes in Earth’s dynamics mostly involve the changing of matter from
one state to another.
To understand the dynamics of Earth and how rocks and minerals are formed and
changed through time, you must have some knowledge of the fundamental structure of matter and how it behaves under various conditions.The solid materials that
make up Earth’s outer layers are called rocks. Most rock bodies are mixtures, or
aggregates, of minerals. A mineral is a naturally occurring compound with a definite chemical formula and a specific internal structure. Because minerals, in turn,
are composed of atoms, to understand minerals we must understand something
about atoms and the ways in which they combine.

Atoms
An atom is the smallest fraction of an element that can exist and still show the
characteristics of that element. Atoms are best described by abstract models constructed from mathematical formulas involving probabilities. They are much too
small to be seen with optical microscopes; recently, however, images of atoms have
been made. An example is shown in Figure 3.1. In its simplest form, an atom is
characterized by a relatively small nucleus of tightly packed protons and neutrons,
with a surrounding cloud of electrons. These are the principal building blocks of
atoms, but many other subatomic particles have been identified in recent years.

54

Minerals

FIGURE 3.1 Image of atoms of silicon produced by a scanning tunneling microscope at the
IBM Research Center, Yorktown Heights, New York. The blue spots are individual silicon atoms,
which are arranged in a regular pattern that repeats itself across the surface. You can also see the
hexagonal arrangement of groups of the atoms. Locally, flaws in the structure are also visible. Images
such as this are helpful in understanding the structure of different minerals. (Courtesy of
International Business Machines Corporation. Unauthorized use not permitted.)

The distinguishing feature of an atom of a given element is the number of protons in the nucleus. The number of electrons and neutrons in an atom of a given
element can vary, but the number of protons is always the same. Each proton carries a positive electrical charge, and the mass of a proton is taken as the unit of
atomic mass, approximately 1.66 ∞ 10–24 g.The neutron, as its name indicates, is electrically neutral and has approximately the same mass as the proton. The electron
is a much smaller particle, with a mass approximately 1/1850 the mass of the proton. It carries a negative electrical charge equal in intensity to the positive charge
of the proton. Because the electron is so small, for practical purposes, the entire
mass of the atom is considered to be concentrated in the protons and neutrons of
the nucleus.The atomic mass is simply the sum of the number of neutrons and protons.
Hydrogen is the simplest of all elements. It consists of one proton in the nucleus and one orbiting electron (Figure 3.2). The next heaviest atom is helium, with
two protons, two neutrons, and two electrons. Each subsequently heavier element
contains more protons, neutrons, and electrons. Figure 3.3 is a simplified chart of
all naturally occurring elements. The elements are arranged in rows, with increasingly heavier elements to the right and bottom. This table is commonly called the
periodic chart. The distinguishing feature of an element is the number of protons
in the nucleus of each of its atoms, often called the atomic number. The number
of electrons and neutrons in the atoms of a given element can vary, but the number of protons is constant.
Atoms normally have the same number of electrons as protons and thus do not
carry an electrical charge. As the number of protons increases in progressively
heavier atoms, the number of electrons also increases. The electrons fill a series of
energy-level shells around the nucleus, each shell having a maximum capacity.The
progressive filling of these shells is reflected in the rows of the periodic chart (Figure 3.3).The electrons in the outer shells control the chemical behavior of the element.

What is the structure of an atom?

55

56

Chapter 3

Isotopes
Although the number of protons in each atom of a given element is constant, the
number of neutrons in the nucleus can vary.This means that atoms of a given element
are not all exactly alike. Iron atoms, for example, have 26 protons but individual atoms
may have 28, 30, 31, or 32 neutrons. These varieties of iron are examples of isotopes;
they all have the properties of iron but differ from one another in mass. Most common elements exist in nature as mixtures of isotopes. Some isotopes are unstable,
emitting particles and energy as they experience radioactive decay to form new, more
stable isotopes.

e—
p+

Ions
Hydrogen

e—

2n+
2p+

Atoms that have as many electrons as protons are electrically neutral, but atoms
of most elements can gain or lose electrons in their outermost shells. If electrons
are gained or lost, an atom loses its electrical neutrality and becomes charged.
These electrically charged atoms are ions. The loss of an electron makes a positively
charged ion because the number of protons then exceeds the number of negatively charged electrons. If an electron is gained, the ion has a negative charge.The
electrical charges of ions are important because the attraction between positive ions
and negative ions is the bonding force that sometimes holds matter together. Like
atoms, ions have distinctive sizes that reflect the number of particles in the nucleus and the number of electrons in the surrounding cloud. Ionic size and ionic charge
control how elements fit together to make solid minerals (Figure 3.3).

e—

Bonding

Helium

FIGURE 3.2

The atomic structures of
hydrogen and helium illustrate the major
particles of an atom. Hydrogen has one
proton (p) in a central nucleus and one
orbiting electron (e). Helium has two
protons (p), two neutrons (n) in the nucleus,
and two orbiting electrons.

What are the distinguishing characteristics of an isotope? Of an ion?

An atom is most stable if its outermost shell is filled to capacity with electrons. The
inner shell can hold no more than 2 electrons. The next shell can hold 8 electrons
and is full in neon (atomic number 10). In heavier elements, the next shell can
have 18 electrons, and the shell after that one can have 32 electrons. Neon, for
example, has 10 protons in the nucleus and 10 electrons, of which 2 are in the
first shell and 8 are in the second shell. A neon atom does not have an electrical
charge. Its two electron shells are complete because the second shell has a limit
of 8 electrons. As a result, neon does not interact chemically with other atoms.
Argon and the other noble gases (the right column on the periodic chart) also
have 8 electrons in their outermost shell, and they normally do not combine with
other elements. Most elements, however, have an incomplete outermost shell.
Their atoms readily lose or gain electrons to achieve a structure like that of argon,
neon, and the other inert gases, with 8 electrons in the outermost shell.
For example, an atom of sodium has only 1 electron in its outermost shell but
8 in the shell beneath (Figure 3.4). If it could lose the lone outer electron, the sodium atom would have a stable configuration like that of the inert gas neon. The
chlorine atom, in contrast, has 7 electrons in its outermost shell, and if it could gain
an electron, it too would attain a stable electron configuration.Whenever possible,
therefore, sodium gives up an electron and chlorine gains one. The sodium atom
thus becomes a positively charged sodium ion, and the chlorine atom becomes a
negatively charged chloride ion. With opposite electrical charges, the sodium ions
and chloride ions attract each other and bond together to form the compound
sodium chloride (common salt, also known as the mineral halite). (A compound
has more than one element in its structure.) This type of bond, between ions of opposite electrical charge, is known as an ionic bond. Such bonds commonly develop between elements that lie far from one another on the periodic table.
Atoms can also attain the electron arrangement of a noble gas, and thus attain stability, by sharing electrons. No electrons are lost or gained, and no ions are formed.
Instead, an electron cloud surrounds both nuclei.This type of bond is a covalent bond
and typically develops between elements that are near one another on the periodic
table. Bonds between two atoms of the element may be of this type; the bonds in an
oxygen molecule (O2) are a good example.The bonds between carbon and hydrogen

57

Minerals

No tendency
to gain or lose
electrons

Strong tendency to
lose electrons

1

H
8

Hydrogen

3

Li

1

4

Oxygen

0.27

Lithium

Na 1

Beryllium

12

1.18

Sodium

19

K1

Mg 2
0.72

Ca 2

21

Sc 3

22

Ti

4

23

V

3

24

Cr

3

1.12

0.14

0.74

0.64

0.62

Potassium

Calcium

Scandium

Titanium

Vanadium

Chromium

Rb 1

38

Sr

2

39

Y3

40

Zr

4

41

Nb 5

1.61

1.26

1.02

0.84

0.74

Rubidium

Strontium

Yttrium

Zirconium

Niobium

55

Cs 1

56

Ba 2

1.74

1.42

Cesium

Barium

87

Fr

1

Francium

88

Ra 2

1.48

Radium

5

57

72

TO

71

Hf

4

73

Ta 5

42

Mo 5

25

74

W6

26

Fe

2

27

Co 2

C

Boron

13

28

Ni

2

29

Cu 2

30

Zn 2

Al

4

7

N

0.16

14

Si

5

8

O

0.13

Carbon

3

15

P

–2

9

F

1.42

Nitrogen

4

5

S

–1

–2

Fluorine

17

Cl

–1

0.54

0.40

0.38

1.84

1.81

Silicon

Phosphorus

Sulfur

Chlorine

Ga 3

32

Ge 4

33

As 3

34

Se 6

35

Br

–1

0.78

0.74

0.69

0.73

0.74

0.62

0.53

0.46

0.42

1.95

Manganese

Iron

Cobalt

Nickel

Copper

Zinc

Gallium

Germanium

Arsenic

Selenium

Bromine

43

44

Tc

Technetium

75

Re 4

Ru 4

45

Rh 3

46

Pd 2

47

Ag 1

48

Cd 2

49

In 3

50

Sn 4

51

Sb 3

52

Te 6

53

I –1

0.62

0.67

0.86

1.15

0.95

0.80

0.69

0.76

0.56

2.16

Ruthenium

Rhodium

Palladium

Silver

Cadmium

Indium

Tin

Antimony

Tellurium

Iodine

76

Os 6

77

Ir

4

78

Pt

2

79

Au 1

80

Hg 2

81

Tl 1

82

Pb 2

83

Bi

3

0.83

0.74

0.60

0.63

0.54

0.62

0.60

0.68

1.02

1.59

1.29

1.17

Hafnium

Tantalum

Tungsten

Rhenium

Osmium

Iridium

Platinum

Gold

Mercury

Thallium

Lead

Bismuth

89

84

10

1.36

Oxygen

16

Helium

Aluminum

31

He

Strong tendency
to gain electrons

0.83

0.61

Molybdenum

Mn 2

6

B3

0.11

Tendency to lose electrons

Magnesium

20

Tendency to share electrons
or gain and lose electrons

Darker colors are major constituents of crust

1.51

37

-2

1.42

Be 2

0.76

11

O

2

Atomic number (protons)
Ionic charge
Symbol
Ionic radius Å
Name of element

Po

85

At

Ne
Neon

18

Ar
Argon

36

Kr

Krypton

54

Xe
Xenon

–1

86

Polonium

Astatine

Metals

Nonmetals

Rn
Radon

TO

92
57

La 3

58

1.16

Lanthanum

89

Ac

Actinium

Ce 3

59

1.14

Cerium

90

Th

Pr

3

Praseodymium

4

1.05
Thorium

91

Pa

Protactinium

60

Nd 3

1.11

Neodymium

92

U

61

Pm 3
1.09

Promethium

62

Sm 3

63

Eu 2

64

Gd 3

65

Tb 3

66

Dy 3

67

Ho 3

68

Er

1.08

1.25

1.05

1.04

1.03

1.02

1.00

Samarium

Europium

Gadolinium

Terbium

Dysprosium

Holmium

Erbium

3

69

Tm 3

70

Yb 3

71

Lu 3

0.99

0.98

0.98

Thullium

Ytterbium

Lutetium

4

1.00
Uranium

FIGURE 3.3

The periodic table of the elements shows the name and symbol of all of the naturally occurring elements. The lightest and simplest
elements are in the upper left; across and toward the bottom, each element is progressively more complex, with increasing numbers of nuclear particles
and electrons. The elements are separated into rows according to the outermost electron shell. Also shown is the charge of the common ion and the
radius for that ion. These properties of an element control how it combines with other elements to form minerals.

in organic materials are also of this type. Many bonds found in natural substances
are intermediate between covalent and ionic bonds. Electrons are “pulled” closer to
the nucleus of one ion than to the other.As a consequence, one part of the molecule
may have a slight charge. The Si-O bond that is so common in minerals is like this.
A third type of bond is the metallic bond. In a metal, each atom contributes
one or more outer electrons that moves relatively freely throughout the entire aggregate of ions. A given electron is not attached to a specific ion pair but moves
about. This sea of negatively charged electrons holds the positive metallic ions together in a crystalline structure and is responsible for the special characteristics of
metals, including their high electrical conductivity and ductile behavior. Except
for a few native elements (such as gold), few minerals have metallic bonds.

States of Matter
The principal differences between solids, liquids, and gases involve the degree of
ordering of the constituent atoms. In the typical solid, atoms are arranged in a
rigid framework.The arrangement in crystalline solids is quite different.The atomic structure of a crystal consists of a regular, repeating, three-dimensional pattern
known as a crystal structure. However, there are some amorphous solids in which
the atomic arrangement is random. Glass is an example of an amorphous solid
that lacks a clearly defined crystalline structure. In such solids, each atom occupies
a more or less fixed position but has a vibrating motion. Changes in crystalline
solids occur as the temperature or pressure changes. For example, as temperature
rises, the vibration of atoms in the structure increases, and atoms move farther and
farther apart. Eventually the bonds between two atoms may break and they become free and able to glide past one another. Melting ensues, and the crystalline
solid passes into the liquid state.
In a liquid, the basic particles are in random motion, but they are packed closely together. They slip and glide past one another or collide and rebound, but they

Why can gaseous, liquid, and solid
forms of a substance have such different physical properties and still have
the same composition?

58

Chapter 3

Sodium atom
loses 1 electron

Chlorine atom
gains 1 electron

Reaction

Sodium ion
Na+

Reaction

Chlorine ion
Cl—

Covalent bond forms
by sharing electrons

Compound sodium chloride forms by
electrical attraction between Na+ and Cl(A) The formation of an ionic bond in sodium
and chloride ions by transfer of an electron from
the outermost shell of a sodium atom to the
outermost shell of a chlorine atom results in a
stable outer shell for each ion.

(B) Covalent bonds form when two atoms
share electrons. The bond between silicon and
oxygen, so common in minerals, is largely of
this type.

FIGURE 3.4 Elements form chemical bonds in several different ways, but all involve
interactions of electrons in the outermost electron shell. Ionic and covalent bonds are two of the
most important in minerals.

are held together by forces of attraction greater than those in gases. This force of
attraction explains why density generally increases and compressibility decreases
as matter changes from gas to liquid to solid. If a liquid is heated, the motion of the
particles increases, and individual atoms or molecules become separated as they
move about at high speeds.
In a gas, the particles are in rapid motion and travel in straight lines until their
direction is changed by collision. Because the individual atoms or molecules are
separated by empty spaces and are comparatively far apart, gases can be markedly compressed and can exert pressure. Gases have the ability to expand indefinitely, and the continuous rapid motion of the particles results in rapid diffusion.
Water undoubtedly provides the most familiar example of matter changing
through the three basic states. At pressures prevailing on Earth’s surface, water
changes from a solid, to a liquid, to a gas in a temperature range of only 100°C. Most
people are familiar with the effects of temperature changes on the state of matter
because of their experience with water as it freezes, melts, and boils. Fewer people
are familiar with the effects of pressure. Under great pressure, water will remain
liquid at temperatures as high as 371°C.
The combined effects of temperature and pressure on water are shown in the
phase diagram in Figure 3.5. An interesting and very important feature of water is
the fact that as it freezes, the solid is actually less dense than the liquid.As a result,
water ice floats rather than sinks. The expansion of water during freezing is important for weathering and in the moderation of Earth’s climate. Because polar ice
floats on the sea, it creates an insulating layer that slows the cooling of the rest of
the sea. If ice did not float, Earth’s oceans may have frozen solid during the ice ages.
Other forms of matter in the solid Earth are capable of similar changes, but
usually their transitions from solid, to liquid, to gas occur at comparatively high
temperatures. At normal room temperature and pressure, 93 of the 106 elements
are solids, 2 are liquids, and 11 are gases. Diagrams similar to Figure 3.5, constructed
from laboratory work on other minerals, provide important insight into the processes operating at the high temperatures and pressures below Earth’s surface.

Pressure (bars)

Minerals
100

Solid

10

Freezing
point at
1 bar

Critical
point

Liquid
Boiling point
at 1 bar

1

0.1

Vapor
0.01
Triple
point
0.001
—100

0

100

200

300

400

Temperature (¡C)

FIGURE 3.5 Temperature and pressure determine the state in which matter exists. In this
diagram, the ranges of temperature and pressure for the various phases of water are shown. The triple
point is the point at which all three phases are in equilibrium. Beyond the critical point the liquid and
gas phases cannot be distinguished. Similar phase diagrams can be constructed for other minerals.

THE NATURE OF MINERALS
A mineral is a natural inorganic solid with a specific internal structure and
a chemical composition that varies only within specific limits. All specimens
of a given mineral, regardless of where, when, or how they were formed,
have the same physical properties (including cleavage, crystal form, hardness, density, color, luster, and streak). Minerals also have restricted stability
ranges.
Minerals are the solid constituents of Earth. Many people think of minerals only
as exotic crystals in museums or as valuable gems and metals; but grains of sand,
snowflakes, and salt particles are also minerals, and they have much in common
with gold and diamonds. A precise definition is difficult to formulate, but for a
substance to be considered a mineral, it must meet the conditions listed above and
described in greater detail below. The differences among minerals arise from the
kinds of atoms they contain and the ways those atoms are arranged in a crystalline
structure.

Natural Inorganic Solids
By definition, only naturally occurring inorganic solids are minerals—that is, natural
elements or inorganic compounds in a solid state. Synthetic products, such as
artificial diamonds, are therefore not minerals in the strict sense. Organic
compounds, such as coal and petroleum, which lack a crystal structure, are also
not considered to be minerals. This criterion is not as important as most of the
others. After all, there is little difference between a synthetic and a natural
gem, other than where they formed. All of its structural, physical, and chemical
properties are shared with its natural counterparts. Likewise, there are organic
solids that have all of the characteristics of minerals.

The Structure of Minerals
The key words in the definition of mineral are internal structure. Minerals can
consist of a single element, such as gold, silver, copper, diamond, or sulfur.
However, most are compounds of two or more elements.The component atoms of
a mineral have a specific arrangement in a definite geometric pattern. All specimens of a given mineral have the same internal structure, regardless of when,
where, and how they were formed. This property of minerals was suspected

Why is the structure of a mineral so
important?

59

STATE OF
THE ART

X-Ray Diffraction and the Structure of Minerals

X-ray
tube

more complicated X-ray diffraction pattern was formed
from a specimen of feldspar. Because feldspars have a much
greater variety of elements, bond types, and structural elements, the diffraction pattern is also more complicated.
X-ray diffraction analysis is the definitive technique that
shows us that each mineral species has its own distinctive
structure that is repeated many times in every grain of the
mineral. It reveals the great symmetry and order found in
the mineral kingdom.

100
K-feldspar
80
60
Intensity of difracted X-rays

With modern methods of X-ray diffraction, we can determine
precisely a mineral’s internal structure and learn much about
the arrangement of its atoms. Diffraction involves the bending of X rays as they pass through a crystalline substance.
The technique is illustrated in the figure below. When a
narrow beam of X rays is passed through a mineral grain,
the X rays are diffracted by the framework of atoms.The individual ions are spaced very closely in the rigid network,
close enough to bend X rays—like a diffraction grating
bends light rays. The diffracted rays cause constructive and
destructive interference—in effect, concentrating the energy of the X rays in some areas and dispersing it in others.
After they leave the crystal, the X rays expose a photographic plate or are detected with a scanning device and
plotted as shown. From the pattern made by the spots or
from measurements of the position and height of the peaks,
the systematic orientation of planes of atoms within the
crystal can be deduced. Such measurements are so precise
that the distances between atoms can be measured and the
size and shape of the electron cloud calculated. Detailed
models of crystal structures showing the position of each
different atom can thus be constructed.
The X-ray diffraction instrument is now the most basic
device for determining the internal structure of minerals,
and geologists use it extensively for precise mineral identification and analysis.
Two typical examples of X-ray spectra are shown on the
chart. The lower curve is the X-ray diffraction pattern for
the mineral quartz. The peaks are created by constructive
interference of the X rays and correspond to specific atomic spacings that are the result of the nearly covalent siliconoxygen bond. The peak positions do not directly reveal the
kinds of atoms, only their distances and arrangements. The

20
0
100
Quartz

80
60
40
20
0
0

Focusing plates

10

20 30 40 50 60 70
Angle of examination (2 Theta)

Photographic film

Crystal

60

40

80

Minerals

Carbon
atoms

Strong covalent
bonds

Diamond

Carbon
atoms

Strong covalent
bonds

Weak
bonds

Graphite

FIGURE 3.6 The internal structure of a mineral controls its physical properties. Diamond and graphite have exactly the same chemical
composition, but the carbon atoms are arranged differently and held together by different types of bonds. Graphite is made of sheets of carbon
stacked on top of one another. It is soft and black. Diamond, the hardest mineral known, is made of carbon atoms bound together in a tight
tetrahedral framework. Most grains of diamond are transparent. (Photographs by Jeffrey A. Scovil)

long ago by mineralogists who observed the many expressions of order in
crystals. Nicolaus Steno (1638–1687), a Danish monk, was among the first to note
this property. He found from numerous measurements that each of the different
kinds of minerals has a characteristic crystal form. Although the size or shape of
a mineral’s crystalline form may vary, similar pairs of crystal faces always meet at
the same angle. This is known as the law of constancy of interfacial angles.
Later, Rene Hauy (1743–1822), a French mineralogist, accidentally dropped a
large crystal of calcite and observed that it broke along three sets of planes only,
so all the fragments had a similar shape (see Figure 3.9). He then proceeded to
break other calcite crystals in his own collection, plus many in the collections of his
friends, and found that all of the specimens broke in exactly the same manner. All
of the fragments, however small, had the shape of a rhombohedron. To explain his
observations, he assumed that calcite is built of innumerable infinitely small rhombohedra packed together in an orderly manner; he concluded that the cleavage
of calcite is related to the ease of parting of such units from adjacent layers. His
discovery was a remarkable advance in understanding crystals. Today we know
that cleavage planes are planes of weakness in the crystal structure and that they
are not necessarily parallel to the crystal faces. Cleavage planes do, however, constitute a striking expression of the orderly internal structure of crystals.
To understand the importance of structure in a mineral, consider the characteristics of diamond and graphite (Figure 3.6). These two minerals are identical in

61

62

Chapter 3

Si+4 0.40

Ni+2 0.69

Mg

K+ 1.51

+2

+3

0.54

Fe

+2

0.78

Na+ 1.18

Ca

0.72

O—2 1.42

Al

OH

—1

Fe+3 0.64

+2

1.12

chemical composition. Both consist of a single element, carbon (C). Their crystal
structures and physical properties, however, are very different. In diamond, which
forms only under high pressure, the carbon atoms are packed closely, and the covalent bonds between the atoms are very strong. Their structure explains why diamonds are extremely hard—the hardest natural substance known. In graphite,
the carbon atoms form layers that are loosely bound. Because of weak bonds, the
layers separate easily, so graphite is slippery and flaky. Because of its softness and
slipperiness, graphite is used as a lubricant and is also the main constituent of common “lead” pencils.The important point to note is that different structural arrangements of exactly the same elements produce different minerals with different properties. This ability of a specific chemical substance to crystallize in more than one
type of structure is known as polymorphism.

1.40

FIGURE 3.7

The relative size and
electrical charge of ions are important
factors governing the suitability of one
ion to substitute for another in a crystal
structure. Silicon can be replaced by
aluminum, iron by magnesium or nickel,
and sodium by calcium.

The Composition of Minerals
A mineral has a definite chemical composition, in which specific elements occur
in definite proportions. Thus, a precise chemical formula can be written to express
the chemical composition—for example, SiO2, CaCO3, and so on. The chemical
composition of some minerals can vary, but only within specific limits. In these
minerals, two or more kinds of ions can substitute for each other in the mineral
structure, a process known as ionic substitution. Ionic substitution results in a
chemical change in the mineral without a change in the crystal structure, so substitution can occur only within definite limits. The composition of such a mineral
can be expressed by a chemical formula that specifies ionic substitution and how
the composition can change.
The suitability of one ion to substitute for another is determined by several factors, the most important being the size and the electrical charge of the ions in question (Figures 3.3 and 3.7). Ions can readily substitute for one another if their ionic
radii differ by less than 15%. If a substituting ion differs in charge from the ion for
which it is substituted, the charge difference must be compensated for by other
substitutions in the same structure in order to maintain electrical neutrality.
Ionic substitution is somewhat analogous to substituting different types of equalsized bricks in a wall. The substitute brick may be composed of glass, plastic, or
whatever, but because it is the same size as the original brick, the structure of the
wall is not affected. An important change in composition has, however, occurred,
and as a result there are changes in physical properties. In minerals, ionic substitution causes changes in hardness and color, for example, without changing the
internal structure.
Ionic substitution is common in rock-forming minerals and is responsible for
mineral groups, the members of which have the same structure but varying composition. For example, in the olivine group, with the formula (Mg, Fe)2SiO4, ions
of iron (Fe+2) and magnesium (Mg+2) can substitute freely for one another because
they have similar charges and sizes (Figure 3.7).The total number of Fe+2 and Mg+2
ions is constant in relation to the number of silicon (Si) and oxygen (O) atoms in
the olivine, but the ratio of iron to magnesium may vary in different samples. The
common minerals feldspar, pyroxene, amphibole, and mica each constitute a group
of related minerals in which ionic substitution produces a range of chemical
composition.

The Physical Properties of Minerals
What determines the physical properties of a mineral?

Because a mineral has a definite chemical composition and internal crystalline
structure, all specimens of a given mineral, regardless of when or where they
were formed, have the same physical and chemical properties. If ionic substitution occurs, variation in physical properties also occurs, but because ionic substitution can occur only within specific limits, the range in physical properties also can
occur only within specific limits. This means that one piece of quartz, for example,

(B) Tetrahedrons of sphalerite (ZnS).

(C) Needles of the rare mineral crocoite (PbCrO4).

(A) Prismatic tourmaline
[Na(Li,Al)3Al6(BO3)3Si6O18(OH)4].

(D) Radiating clusters of long slender needles of the zeolite
mineral mordenite (Ca,Na2,K2)(Al2Si10)(O24·7H2O).

FIGURE 3.8

Crystal form is an important physical
property showing the arrangement of atoms in a mineral.
(Photographs by Jeffrey A. Scovil)

(E) Cubes of pyrite (FeS2), commonly known as fool’s gold.

63

64

Chapter 3

(A) One plane of cleavage in mica produces thin plates or sheets.

(B) Two planes of cleavage at right angles in feldspar produce blocky
fragments.

(C) Three planes of cleavage at right angles in halite produce cubic
fragments.

(D) Cleavage of calcite occurs in three planes that do not intersect at
right angles, forming rhombohedrons.

FIGURE 3.9

Cleavage reflects planes of weakness within a crystal structure.

is as hard as any other piece, that it has the same density, and that it breaks in the
same manner, regardless of when, where, or how it was formed.
The more significant and readily observable physical properties of minerals are
crystal form, cleavage, hardness, density, color, luster, and streak.
If a crystal is allowed to grow in an unrestricted environment, it develops natural crystal faces and assumes a specific geometric crystal form. The shape of a
crystal is a reflection of the internal structure and is an identifying characteristic
for many mineral specimens (Figure 3.8). If the atoms are arranged in a long chain,
the crystal may be shaped like a needle. If the atoms are arranged in a boxlike network, the crystal will likely be in the form of a cube. If the space for growth is restricted, however, smooth crystal faces cannot develop.
Cleavage is the tendency of a crystalline substance to split or break along smooth
planes parallel to zones of weak bonding in the crystal structure (Figure 3.9). If the
bonds are especially weak in a given plane, as in graphite, mica, or halite, perfect
cleavage occurs with ease. Breaking the mineral in any direction other than along
a cleavage plane is difficult (Figure 3.9). In other minerals, the differences in bond
strength are not great, so cleavage is poor or imperfect. Cleavage can occur in
more than one direction, but the number and direction of cleavage planes in a
given mineral species are always the same. Some minerals have no weak planes in
their crystalline structure, so they do not have cleavage and break along various
types of fracture surfaces. Quartz, for example, characteristically breaks by conchoidal fracture—that is, along curved surfaces, like the curved surfaces of chipped
glass. Cleavage planes and crystal faces should not be confused with the facets
found on gems. Facets are produced by grinding and polishing the surface of a

Minerals

65

TABLE 3.1
Mohs Hardness Scale
Hardness

Mineral

1
2

Talc
Gypsum

Test

Fingernail
3

Calcite

4
5

Fluorite
Apatite

Copper coin

Knife blade
or glass plate

FIGURE 3.10

Hardness reflects the strength of the atomic bonds inside the mineral. Gypsum
has a hardness of 2 on Mohs hardness scale. It is a very soft mineral and can easily be scratched with
a fingernail.

mineral grain and do not necessarily correspond to cleavage directions. For example, diamond lacks cleavage altogether but can be polished so that a single crystal will have many shiny faces.
Hardness is a measure of a mineral’s resistance to abrasion. It is in effect a measure of the strength of the atomic bonds in a crystal. This property is easily determined and is used widely for field identification of minerals. More than a century
ago, Friedrich Mohs (1773–1839), a German mineralogist, assigned arbitrary
relative numbers to 10 common minerals in order of their hardness. He assigned
the number 10 to diamond, the hardest mineral known. Softer minerals were
ranked in descending order, with talc, the softest mineral, assigned the number 1.
The Mohs hardness scale (Table 3.1) provides a standard for testing minerals for
preliminary identification. Gypsum, for example, has a hardness of 2 and can be
scratched by a fingernail (Figure 3.10). More exacting measures of hardness show
that diamond is by far the hardest mineral.
Density is the ratio of the weight of a substance to its volume. For example, at
room temperature, 1 cm3 of water weighs 1 g; the density is thus 1 g/cm3. On the other
hand, 1 cm3 of solid lead weighs a little over 11 g, and thus its density is 11 g/cm3.
Density is one of the more precisely defined properties of a mineral. It depends
on the kinds of atoms making up the mineral and how closely they are packed in
the crystal structure. Clearly, the more numerous and compact the atoms, the higher the density. Most common rock-forming minerals have densities that range from
2.65 g/cm3 (for quartz) to about 3.37 g/cm3 (for magnesium olivine). Iron-rich
olivine is even denser (4.4 g/cm3) because iron has a higher atomic weight than
magnesium. Some metallic minerals have much higher densities. For example,
native gold has a density of about 20 g/cm3 and native iron has a density of
almost 8 g/cm3. At high pressures, the densities of most minerals increase because
the atoms are forced to be closer together.At high temperatures, their densities decrease as the atoms move farther apart.
Color is one of the more obvious properties of a mineral. Unfortunately, it is not
diagnostic. Most minerals are found in various hues, depending on such factors as
subtle variations in composition and the presence of inclusions and impurities.
Quartz, for example, ranges through the spectrum from clear, colorless crystals
to purple, red, white, yellow, gray, and black.
Luster describes the appearance of light reflected from a mineral’s surface. Luster is described only in subjective, imprecise terms.There are two basic kinds of luster: metallic and nonmetallic. Minerals with a metallic luster shine like metals.
Nonmetallic luster ranges widely, including vitreous (glassy), porcelainous, resinous,

6
7

K-feldspar
Quartz

8
9
10

Topaz
Corundum
Diamond

Steel file

66

Chapter 3

2000

1000

0
500

1000
1500
Temperature (¡C)

FIGURE 3.11

Liquid

Cristobalite

3000

High
Quartz

Tridymite

Pressure (bars)

4000

Low Quartz

5000

2000

The stable form of
SiO2 depends on pressure and
temperature. The colored areas show the
range of temperature and pressure over
which each of five different minerals are
stable. Quartz, for example, is stable at
intermediate temperatures over a wide
range of pressures. Other minerals of the
same composition (SiO2), but with
different atomic arrangements, are stable
at other pressures and temperatures.

and earthy (dull). The luster of a mineral is controlled by the kinds of atoms and
by the kinds of bonds that link the atoms together. Many minerals with covalent
bonds have a brilliantly shiny luster, called adamantine luster, as in diamond. Ionic
bonds create more vitreous luster, as in quartz. Metallic bonding in native metals,
such as gold, also has its characteristic luster.
Streak refers to the color of a mineral in powder form and is usually more diagnostic than the color of a large specimen. For example, the mineral pyrite (fool’s
gold) has a gold color but a black streak, whereas real gold has a gold streak—the
same color as that of larger grains. Streak is tested by rubbing a mineral vigorously against the surface of an unglazed piece of white porcelain. Minerals softer
than the porcelain leave a streak, or line, of fine powder. For minerals harder
than porcelain, a fine powder can be made by crushing a mineral fragment. The
powder is then examined against a white background.
Magnetism is a natural characteristic of only a few minerals, like the common
iron oxide magnetite. Although only a few minerals can be identified using this
property, magnetism is an important physical property of rocks that is used in
many investigations of how Earth works (see page 604).

Stability Ranges
Another important feature of each mineral is that it is stable only over a fixed
range of conditions. We call a mineral stable if it exists in equilibrium with its environment. In such a case, there is little tendency for further change. The environment that exists when a mineral crystallizes determines which of the many thousands of minerals will form.The environmental conditions that determine whether
a particular mineral is stable are mainly pressure, temperature, and composition.
We have already examined the stability ranges for the various states of water
(see Figure 3.5), and we can use similar phase diagrams to represent the range
of conditions over which a specific mineral is stable. Figure 3.11 shows the
names and stability fields for various minerals with the chemical formula SiO2.
Quartz is the most common of these minerals because it is stable over the range
of temperatures and pressures found near Earth’s surface. However, if the temperature is increased to 1300°C at a pressure of 1000 bars (a depth in Earth of
about 3 km), the arrangement of the atoms in quartz will change to form a different mineral called tridymite, which has its own structure and distinctive physical
properties. For example, quartz has a density of 2.65 g/cm3 and tridymite has a density of about 2.26 g/cm3. If the temperature is increased to 1600°C, still another
change occurs as tridymite converts to cristobalite with a density of 2.33 g/cm3. In
the absence of water, pure SiO2 melts only at a temperature higher than 1700°C.
Changes in pressure can also induce minerals to break down and form new species
that are stable under the new conditions. Metamorphic processes, discussed in
more detail in Chapter 6, are driven by the tendency for minerals to react and
change as their environment changes.
Although minerals have distinctive stability ranges, they may remain in existence far from those conditions. A mineral existing outside of its stability range
is called metastable. Metastability occurs if the reactions to form new minerals
from preexisting minerals are very slow. Such barriers are common at Earth’s
surface, where low temperatures make atomic movements and reactions very
sluggish in solids. Thus, tridymite has been found at temperatures far below the
range of temperatures shown in Figure 3.11. Moreover, feldspars are common at
Earth’s surface, even though clay minerals are more stable in the presence of
water. Despite these reaction barriers at low temperature, it is useful to keep in
mind the approximate range of temperatures and pressures over which a given
mineral is stable.

Minerals

67

THE GROWTH AND DESTRUCTION OF MINERALS
Minerals grow as matter changes from a gaseous or liquid state to a solid
state or when one solid recrystallizes to form another. They break down as
the solid changes back to a liquid or a gas. All minerals came into being
because of specific physical and chemical conditions, and all are subject to
change as these conditions change. Minerals, therefore, are an important
means of interpreting the changes that have occurred in Earth throughout
its history.

Crystal Growth
Even though minerals are inorganic, they can grow. Growth is accomplished by
crystallization, which occurs by the addition of ions to a crystal face. As noted
above, an environment suitable for crystal growth includes (1) proper concentration of the kinds of atoms or ions required for a particular mineral and (2) proper temperature and pressure.
The time-lapse photographs in Figure 3.12 show how crystals grows from a liquid in an unrestricted environment. Although the size of each crystal increases, its
form and internal structure remain the same. New atoms are added to the faces
of the crystal, parallel to the plane of atoms in the basic structure. Some crystal
faces, however, grow faster than others.As a result of these different growth rates,
the crystal may become elongated in one direction. Thus, the ideal crystal shape
reflects not only the arrangement of atoms inside the crystal, but it also controlled
by which faces grow faster or slower. You can see that all of the crystals in Figure
3.12 have the same idealized shape, because they are all the same mineral. The
mineral grains in the chapter opening photograph show the dramatic results of
growth in an unrestricted environment. These minerals crystallized from a watery
solution in an open vug within an ancient series of lava flows. Each crystal was free
to grow to its ideal shape with little interference from other crystals. It is easy to
tell that there are two different kinds of minerals from their ideal shapes.
In contrast, where space is restricted, a crystal may not grow to form its ideal
crystal shape. Where a growing crystal encounters a barrier (such as another crystal), it simply stops growing.This process is illustrated in Figure 3.12. Note how the
vertical crystal grew between 10 and 30 seconds.At 30 seconds, it has impinged on
a nearly horizontal crystal and stopped growing. However, the more horizontal

How can a mineral, which is inorganic,
grow?

Elapsed Time
0 sec.

10 sec.

30 sec.

1 min.

Liquid

Growing
crystals

Solid
FIGURE 3.12

Crystal growth can be recorded by time-lapse photography. Each crystal grows as atoms in the surrounding liquid lock onto the
outer faces of the crystal structure.

68

Chapter 3

Growth
continued
x

y

z
y

Growth
eliminated

z
x
(A)
(B)

(C)

Figure 3.13

Crystals growing in a restricted environment do not develop perfect crystal faces. (A) Where growth is unrestricted, all crystal
faces grow with equal facility. (B) In a restricted environment, growth on certain crystal faces, such as x and y, is terminated but growth on the
faces labeled z continues. (C) The final shape of the crystal is determined by the geometry of the available space in which it grows.

crystal grows throughout the sequence because there were no restrictions to its
growth.
Figure 3.13 shows how crystal growth occurs in a restricted environment. A
crystal growing from a liquid in a restricted space assumes the shape of the confining area, and well-developed crystal faces do not form. The external form of the
crystal can thus take on practically any shape, but its internal structure is in no way
modified. The mineral’s internal structure remains the same; its composition is
unaffected, and no changes in its physical and chemical properties occur. The only
modification is a change in the shape of the crystal.
Crystal growth in restricted spaces is common for rock-forming minerals. In a
still molten lava flow or in an aqueous solution, many crystals grow at the same time
and must compete for space. As a result, in the later stages of growth, crystals in
rocks commonly lack well-defined crystal faces and typically interlock with adjacent crystals to form a strong, coherent mass (Figure 3.14). This interlocking texture is especially common in igneous rocks, which form by crystallization from
molten rock material.
Most crystals are rather small, measuring from a few tenths of a millimeter to
several centimeters in diameter. Some are so small they can be seen only when
enlarged thousands of times with a high-powered electron microscope (Figure
3.15). Where crystallization occurs from a mobile fluid in an unrestricted environment, however, crystals can grow to enormous sizes (Figure 3.16).

Destruction of Crystals
Mineral grains can be destroyed in many different ways. Minerals melt by removal
of outer atoms from the crystal structure as they enter a less organized liquid state.
The heat that causes a crystal to melt increases atomic vibrations enough to break

FIGURE 3.14

Interlocking texture develops if crystals grow in a restricted environment. Crystals grow into one another when
they are forced to compete for space. Such textures are common in igneous rocks which form form molten magma. (see Chapter 4).

Minerals

(A) Sand grains magnified 50 times. Small
crystals of clay form between the grains.

(B) Clay crystals coating sand grains
magnified 1000 times.

69

(C) Clay crystals magnified 2000 times.

FIGURE 3.15

Submicroscopic crystals of hexagonal plates of clay growing in the pore spaces between sand grains can be seen with an electron
microscope. Each crystal contains all of the physical and chemical properties of the mineral, even though each one is extremely small. (Courtesy of
Harry W. Fowkes)

the bonds holding an atom to the crystal structure. Similarly, atoms can be “pried”
loose and carried away by a solvent, usually (in geologic processes) water. Crystals begin to break down or dissolve at the surface and the reaction moves inward.
Mineral grains can also be destroyed as their constituent atoms become rearranged in the solid state. Such recrystallization processes are especially common
deep inside the crust and mantle, where heat and pressure cause some crystal structures to collapse and new minerals, with a denser, more compact atomic structure
(Figure 3.17) to form in their place. In this case, the atoms do not move far, but new
bonds form and new internal structures are created. The new mineral grains have
different physical properties, like cleavage, luster, hardness, and density.

(A) Open structure at low pressure.

(B) Densely packed structure at
high pressure.

FIGURE 3.17
FIGURE 3.16

Large crystals can form where there is
ample space for growth, as in caves. These crystals of gypsum
are more than 1 m long.

Under high pressure, the
atomic structure of a mineral can collapse
into a denser form, in which the atoms are
more closely packed. Although the physical
properties change, the chemical composition
may remain the same.

70

Chapter 3

SILICATE MINERALS

TABLE 3.2
Concentrations of the
Most Abundant Elements
in Earth’s Crust (by weight)
Element
O
Si
Al
Fe
Ca
Na
K
Mg
Ti
H
P
Mn
S
C

Percentage
46.60
27.72
8.13
5.00
3.63
2.83
2.59
2.09
0.44
0.14
0.12
0.10
0.05
0.03

After B. Mason and C. B. Moore, Principles of
Geochemistry, 4th ed. (New York: Wiley, 1982).

More than 95% of Earth’s crust is composed of silicate minerals, a group
of minerals containing silicon and oxygen linked in tetrahedral units, with
four oxygen atoms to one silicon atom. Several fundamental configurations
of tetrahedral groupings are single chains, double chains, two-dimensional
sheets, and three-dimensional frameworks.
Although more than 4000 minerals have been identified, 95% of the volume of
Earth’s crust is composed of a group of minerals called the silicates. This should
not be surprising because silicon and oxygen constitute nearly three-fourths of the
mass of Earth’s crust (Table 3.2) and therefore must predominate in most rockforming minerals. Silicate minerals are complex in both chemistry and crystal structure, but all contain a basic building block called the silicon-oxygen tetrahedron.
Nearly covalent Si-O bonds form a complex ion [(SiO4)4–] in which four large oxygen ions (O2+) are arranged to form a four-sided pyramid with a smaller silicon ion
(Si4+) bonded between them (Figure 3.18). This geometric shape is known as a
tetrahedron. The major groups of silicate minerals differ mainly in the arrangement of such silicate tetrahedrons in their crystal structures.
Perhaps the best way to understand the unifying characteristics of the silicates,
as well as the reasons for the differences, is to study the models shown in Figure
3.19. These were constructed on the basis of X-ray studies of silicate crystals.
Silicon-oxygen tetrahedrons combine to form minerals in two ways. In the simplest combination, the oxygen ions of the tetrahedrons form bonds with other
elements, such as iron or magnesium. Olivine is an example. Most silicate minerals, however, are formed by the sharing of an oxygen ion between two adjacent
tetrahedrons. In this way, the tetrahedrons form a larger ionic unit, just as beads
are joined to form a necklace.The sharing of oxygen ions by the silicon ions results
in several fundamental configurations of tetrahedral groups. These structures define the major silicate mineral groups:
1.
2.
3.
4.
5.

Crystal Models

Isolated tetrahedrons (example: olivine)
Single chains (example: pyroxene)
Double chains (example: amphibole)
Two-dimensional sheets (examples: micas, chlorite, and clays)
Three-dimensional frameworks (examples: feldspars and quartz)

The unmatched electrons of the silicate tetrahedron are balanced by various metal
ions, such as ions of calcium, sodium, potassium, magnesium, and iron. The silicate minerals thus contain silicon-oxygen tetrahedrons linked in various patterns
by metal ions. Considerable ionic substitution can occur in the crystal structure. For
example, sodium can substitute for calcium, or iron can substitute for magnesium.
Minerals of a major silicate group can thus differ chemically from one another but
have a common silicate structure.
O

Si

FIGURE 3.18

The silicon-oxygen tetrahedron is the basic building block of the silicate minerals. In
this figure, the diagram on the right is expanded to show the position of the small silicon atom. Four large
oxygen ions are arranged in the form of a pyramid (tetrahedron), with a small silicon ion covalently
bonded into the central space between them. This is the most important building block in geology
because it is the basic unit for 95% of the minerals in Earth’s crust.

Minerals

Isolated

Single chain

Two-dimensional sheet

Double chain

Three-dimensional framework

FIGURE 3.19 Silicon-oxygen tetrahedral groups can form various structures by the sharing of oxygen
ions among silicon ions. A small silicon ion lies at the center of each tetrahedral unit. In general, various types
of metal ions complete the mineral structure; they are not shown here.

ROCK-FORMING MINERALS
Fewer than 20 kinds of minerals account for the great bulk of Earth’s crust
and upper mantle. The most common silicate minerals are feldspars, quartz,
micas, olivine, pyroxenes, amphiboles, and clay minerals. Important nonsilicates are calcite, dolomite, halite, and gypsum.
Most of Earth’s crust and upper mantle are composed of silicate minerals in which
the common elements—such as iron, magnesium, sodium, calcium, potassium,
and aluminum—combine with silicon and oxygen.The identification of these minerals presents some special problems. Rock-forming minerals rarely have welldeveloped crystal faces because (1) they grow by crystallization from melts (e.g.,
magmas) or from aqueous solutions (e.g., seawater) and vigorously compete for
space; (2) they are abraded as they are transported as sediment; or (3) they are
deformed under high temperature and pressure. In addition, most rock-forming
mineral grains are small, generally less than the size of your little fingernail, so
their physical properties may be difficult to see without a hand lens or microscope.
Further complications arise because most rock-forming mineral groups have
variable compositions attributable to ionic substitution in the crystal structure.
As a result, color, hardness, and other physical properties may be variable.

71

72

Chapter 3

It is important for you to become familiar with the general characteristics of
each of the major rock-forming mineral groups (feldspars, quartz, micas, olivines,
pyroxenes, amphiboles, clays, calcite, dolomite, halite, and gypsum) and to know
something about their physical properties, their mode of origin, the environment
in which they form, and their genetic significance. Some of the characteristics of
these, as well as other important but less common minerals, are listed in Table 3.3.
You will find the following summary of each mineral group to be much more meaningful if you examine a specimen of a rock containing the mineral while you study
the written description.
A careful examination of the minerals that make up granite is a good beginning.
The polished surface of granite (Figure 3.20) shows that the rock is composed of
myriad mineral grains of different sizes, shapes, and colors. Although the minerals
interlock to form a tight, coherent mass, each has distinguishing properties.

Felsic Silicate Minerals
One large group of silicate minerals includes the major constituents of continental crust: feldspars and quartz.These are commonly known as felsic minerals. (They
are sometimes called sialic because they are rich in silicon and aluminum.) In
addition to being the major constituents of continental crust, the felsic minerals
also have low densities and crystallize at low temperatures in magmas.
Feldspars are the most abundant minerals in granite, a common crustal rock.The
granite in Figure 3.20 consists largely of a pink, porcelainous mineral that has a rectangular form and a milky-white mineral that is somewhat smaller but similarly
shaped. These are feldspars (German, “field crystals”), the most abundant minerals in Earth's crust, comprising about 50%.The feldspars have good cleavage in two
directions, a porcelainous luster, and a hardness of about 6 on the Mohs hardness
scale. The crystal structure involves a complex three-dimensional framework of
silicate tetrahedrons (Figure 3.19). Considerable ionic substitution gives rise to
two major types of feldspars: potassium feldspar (K-feldspar) and plagioclase
feldspar. Potassium feldspar (KAlSi3O8) is commonly pink in granitic rocks. Plagioclase feldspar (shown in gray in the sketch) permits complete substitution of
sodium (Na) for calcium (Ca) in the crystal structure, giving rise to a compositional range from NaAlSi3O8 to CaAl2Si2O8. Moreover, most grains of plagioclase
have distinctive, closely spaced striations on their cleavage planes. Plagioclase in
granite is rich in sodium. Feldspars (with a density of 2.7 g/cm3) are common in most
igneous rocks, in many metamorphic rocks, and in some sedimentary rocks. Consequently, the continental crust has a characteristically low density (ranging from
2.6 to 2.7 g/cm3), controlled by the shear abundance of feldspar and quartz.
Quartz forms the glassy, irregularly shaped grains in Figure 3.20. It usually grows
in the spaces between the other minerals.As a result, quartz in granite typically lacks
well-developed crystal faces.When quartz crystals are able to grow freely, their form
is elongated, has six sides, and terminates in a point, but well-formed crystals are
rarely found in rocks. In sandstone, quartz is abraded into rounded sand grains.
Quartz is abundant in all three major rock types. It has the simple composition
SiO2 and is distinguished by its hardness (7), its conchoidal fracture, and its glassy
luster. Pure quartz crystals are colorless, but slight impurities produce a variety of
colors. Quartz is made of silicate tetrahedrons linked together in a tight framework. All of the bonds are between Si and O; it includes no other elements. As a
result, quartz is very hard, and, because all of the bonds have the same strength,
it lacks cleavage. Quartz is stable both mechanically (it is very hard and lacks
cleavage) and chemically (it does not react with elements at or near Earth’s surface). It is therefore a difficult mineral to alter or break down once it has formed.
Micas are the tiny black, shiny grains in Figure 3.20. These distinctive minerals are potassium aluminum silicates. Micas are readily recognized by their perfect one-directional cleavage, which permits breakage into thin, elastic flakes. Mica
is a complex silicate with a sheet structure, which is responsible for its perfect

Minerals

TABLE 3.3
Name

Earth’s Common Minerals

Composition

Cleavage/
Fracture

Color

Hardness Density
(g/cm3)

Comments

Amphibole

Ca2(Mg,Fe)5Si8O22(OH)2

Two at 60° and 120°

Black to green

5–6

3.2

Bauxite

AlO(OH)

One perfect

White

6.5

3.4

Aluminum ore,
mineral diaspore

Beryl

Be3Al2Si6O18

One poor

Green, blue, red

8

2.7

Emerald is gem variety
Hexagonal prisms

Biotite

K(Mg,Fe)3AlSi3O10(OH)2

One perfect

Black to dark brown

2.5–3

3

Splits into thin sheets

Calcite

CaCO3

Three perfect
Rhombohedral

Colorless, white

3

2.7

Bubbles in dilute acid

Chalcopyrite

CuFeS2

Fracture

Brassy, golden yellow
Metallic luster

4

4.3

Copper ore

Chlorite

(Mg,Fe)5Al2Si3O10(OH)8

One perfect

Green

2

2.5

Foliated masses

Clay

Al2Si2O5(OH)4

One perfect

White to brown

2

2.0–2.5

Common in soils

Corundum

Al2O3

Fracture

Brown or blue

9

4

Rubies and sapphires

10

3.5

Hardest mineral known

Diamond

C

Fractures

Transparent
Adamantine luster

Dolomite

CaMg(CO3)2

Three perfect

Transparent to white

3.5–4

2.8

Bubbles in acid when
powdered

Fluorite

CaF2

Perfect

Transparent, green,
purple, yellow

4

3.2

Fluorine ore

Galena

PbS

Three perfect
Cubic

Black to silver
Metallic luster

2.5

7.6

Lead ore

Garnet

Ca3Al2Si3O12

Conchoidal
fracture

Red to brown
Vitreous luster

6.5–7

3.6

Graphite

C

One perfect

Black

1–2

2.1

Compare with diamond

Gypsum

CaSO4•2H2O

One perfect
Two good

Transparent to white

2

2.3

Used in plasterboard

Halite

NaCl

Three perfect
Cubic

Transparent to white

2.5

2.2

Table salt

Hematite

Fe2O3

None

Red to silvery gray
Metallic or earthy

6

5.3

Iron ore

K-feldspar

KAlSi3O8

Two at right angles

White to gray
or pink

6

2.6

Kyanite

Al2SiO5

One perfect
One poor

White to light blue

5–7

3.6

Long-bladed aggregates

Magnetite

Fe3O4

Conchoidal
Irregular

Black
Metallic luster

6

5.2

Magnetic

Muscovite

KAl3Si3O10(OH)2

One perfect

Colorless to
light brown

2–2.5

2.8

Splits into translucent sheets

Olivine

(Mg,Fe)2SiO4

Conchoidal

Green to brown

6.5

3.4

Gem peridot

Plagioclase

NaAlSi3O8
CaAl2Si2O8

Two at right angles

White to gray

6

2.7

Striations on cleavage planes
Most common mineral at surface

Pyrite

FeS2

Uneven fractures

Brassy to golden
yellow

6.5

5

Fool’s gold; well-formed cubes
common

Pyroxene

(Mg,Fe)SiO3

Green to dark
brown or black

6

3.3

Quartz

SiO2

Conchoidal fracture

Colorless, also
gray, purple, other

7

2.7

Serpentine

Mg6Si4O10(OH)8

Splintery fracture
Asbestos fibrous

Green to brown
Silky or waxy luster

2.5

2.5

Sillimanite

Al2SiO5

One perfect

Colorless to white

6–7

3.2

Staurolite

Fe2Al9Si4O22(OH)2

One poor

Brown to red

7

3.8

Talc

Mg3Si4O10(OH)2

One perfect

White to light green

1

2.8

Soft, soapy masses

Zeolite

Complex hydrous
silicates

One perfect

Colorless to light
green

4–5

2.2

Earthy, but may form
radiating crystals in cavities

Two at about 90°

Six-sided elongate crystals

Long, slender crystals

73

74

Chapter 3

Quartz

Plagioclase
(A) A polished surface of a granite,
shown at actual size, displays mineral
grains of different sizes, shapes, and
colors.

Potassium
Feldspar

Biotite

Quartz

Plagioclase

Potassium
Feldspar

Biotite
(B) An exploded diagram of (A)
shows the relative size and the shape
of individual mineral grains.

FIGURE 3.20

Mineral grains in a granite, a common rock in continental crust, form a tight, interlocking texture because each mineral is forced to
compete for space as it grows. The most common minerals in granite are the felsic minerals: quartz, plagioclase feldspar, and potassium feldspar.

cleavage. Two common varieties occur in rocks: muscovite [KAl3Si3O10(OH)2],
which is white or colorless and is found along with felsic minerals, and biotite
[K(Mg, Fe)3Si3AlO10(OH)2], a black mica, rich in iron and magnesium that
belongs to the category of mafic minerals discussed below. Both types of mica contain water in the form of hydroxyl ions (OH–). The densities of these minerals are
also distinctive, with biotite (about 3 g/cm3) denser than muscovite (about 2.8
g/cm3). Mica is abundant in granites and in many metamorphic rocks and is also
a significant constituent of many sedimentary rocks.

Mafic Silicate Minerals
Another category of silicate minerals is the mafic minerals, so named because they
contain much magnesium and iron. These minerals contrast with felsic minerals
and generally range from dark green to black and have high densities. Biotite is classified in this general group, together with the olivine, pyroxene, and amphibole.

Minerals

Plagioclase

75

Olivine

(A) In a hand specimen, only a few large grains of green olivine can be
seen. The dark spots are gas bubbles frozen into the once molten rock.
Plagioclase

Pyroxene

Olivine

Glass

(B) Viewed through a microscope, the mineral grains form an
interlocking texture. Plagioclase feldspar crystals typically form small
lathlike grains between the mafic minerals.

FIGURE 3.21

Pyroxene
Glass bubble
(C) An exploded diagram of (B) shows the size and shape of individual
mineral grains.

Mineral grains in basalt are microscopic and are dominated by mafic minerals. Basalt is a mafic volcanic rock common in the

oceanic crust.

In granite, biotite is common, but the other mafic minerals are rare or absent.
The mafic minerals are common, however, in Earth’s mantle and in oceanic
crust. They generally crystallize at higher temperatures and have higher densities
than felsic minerals. Let us examine basalt, a common mafic volcanic rock, to see
what these minerals are like (Figure 3.21).
Olivine is the only mineral clearly visible in the hand specimen in Figure 3.21; it
is a green, glassy mineral. Olivine is a silicate in which iron and magnesium substitute freely in the crystal structure. The composition is expressed as (Mg,Fe)2SiO4.
Olivine is composed of isolated Si-O tetrahedrons linked together by magnesium or
iron ions (Figure 3.19).This hard mineral is characterized by an olive-green color (if
magnesium is abundant) and a glassy luster. In rocks, it rarely forms crystals larger
than a millimeter in diameter. Like most mafic minerals, olivine has a relatively
high density (about 3.3 g/cm3) and typically forms at high temperatures. It is probably a major constituent of the upper mantle. At depths of about 400 km in the
mantle, olivine is no longer stable and recrystallizes to form an even denser mineral with the same elemental composition.
Pyroxenes are high-temperature minerals also found in many mafic rocks in
the crust and mantle. In Figure 3.21, pyroxene occurs as microscopic crystals, but
some basalts contain larger grains of this mineral, which typically range from dark

76

Chapter 3

FIGURE 3.22

Amphibole crystals were among the first to crystallize in this “granitic” rock and
therefore have well-developed crystal faces. The largest grain is about 3 cm long.

green to black.Their internal structure consists of single chains of linked Si-O tetrahedrons (Figure 3.19). Pyroxene crystals commonly have two directions of cleavage that intersect at right angles.
Amphiboles (Figure 3.22) have much in common with the pyroxenes.Their chemical compositions are similar, except that amphiboles contain hydroxyl ions (OH–)
and pyroxenes do not. The minerals also differ in structure. The internal structure
consists of double chains of silicon-oxygen tetrahedrons (Figure 3.19). The amphiboles produce elongate crystals that cleave perfectly in two planes, which are not at
right angles. Amphibole ranges from green to black. This mineral is common in
many igneous and metamorphic rocks. Hornblende [NaCa(Mg,Fe)5AlSi7O22(OH)2]
is the most common variety of amphibole. The density of a typical amphibole is
about 3.2 g/cm3.
A dangerous form of amphibole is asbestos, once used widely to make fireproof
fabrics, tiles, and as insulation in buildings. Miners working in old dusty mines became sick as small cleavage fragments of a specific type of this mineral became
lodged in their lungs, especially in conjunction with cigarette smoking.The incidence
of this noncancerous lung disease in modern mines with dust controls is much lower.
Fortunately, most asbestos used in construction consists of an entirely different mineral, and the hazard to people is much less than commonly supposed.

Clay Minerals
The clay minerals form another important group of silicate minerals. They are a
major part of the soil and are thus encountered more frequently in everyday experience than many other minerals. Clay minerals form at Earth’s surface, where
air and water react with various silicate minerals, breaking them down to form clay
and other products. Like the micas, the clay minerals are sheet silicates (Figure
3.19), but their crystals are usually microscopic and are most easily detected with
an electron microscope (Figure 3.15). More than a dozen clay minerals can be
distinguished on the basis of their crystal structures and variations in composition.
A common clay mineral, kaolinite, has the formula Al4Si4O10(OH)8 and a low
density of about 2.6 g/cm3.

Minerals

Nonsilicate Minerals
Some important rock-forming minerals are not silicate minerals. Most of these
minerals are carbonates or sulfates and typically form at low temperatures and
pressures near Earth’s surface.
Calcite is composed of calcium carbonate (CaCO3), the principal mineral in
limestone. It can precipitate directly from seawater or is removed from seawater by organisms as they use it to make their shells. Calcite is dissolved by groundwater and reprecipitated as new crystals in caves and fractures in rock. It is usually transparent or white, but the aggregates of calcite crystals that form
limestone contain various impurities that give them gray or brown hues. Calcite
is common at Earth’s surface and is easy to identify. It is soft enough (hardness
of 3) to scratch with a knife, and it effervesces in dilute hydrochloric acid. It has
perfect cleavage in three planes, which are not at right angles, so that cleaved
fragments form rhombohedra (see Figure 3.9). Besides being the major constituent of limestone, calcite is the major mineral in the metamorphic rock marble. Calcite has a density of about 2.7 g/cm3.
Dolomite is a carbonate of calcium and magnesium [CaMg(CO3)2]. Large crystals form rhombohedra, but most dolomite occurs as granular masses of small crystals. Dolomite is widespread in sedimentary rocks, forming when calcite reacts
with solutions of magnesium carbonate in seawater or groundwater. Dolomite can
be distinguished from calcite because it effervesces in dilute hydrochloric acid
only if it is in powdered form. Dolomite has a density of nearly 2.9 g/cm3.
Halite and gypsum are the two most common minerals formed by evaporation
of seawater or saline lake water. Halite, common salt (NaCl), is easily identified
by its taste. It also has one of the simplest of all crystal structures; the sodium
and chloride ions form a cubical array. Most physical properties of halite are
related to this structure. Halite crystals cleave in three planes, at right angles, to
form cubic or rectangular fragments (Figure 3.9). Salt, of course, is very soluble
and readily dissolves in water.
Gypsum is composed of calcium sulfate and water (CaSO4·2H2O). It forms crystals that are generally colorless, with a glassy or silky luster. It is a very soft mineral and can be scratched easily with a fingernail. It cleaves perfectly in one plane to
form thin, nonelastic plates (Figure 3.10). See the GeoLogic discussion at the end
of the chapter for more information about the internal structure of gypsum. Gypsum occurs as single crystals, as aggregates of crystals in compact masses (alabaster),
and as a fibrous form (satin spar).
Oxide minerals lack silicon as well and include several economically important
iron oxides, such as magnetite and hematite (Table 3.3). Magnetite is particularly
interesting because it is one of only a very few minerals that are naturally magnetic.
A wide variety of other minerals have been identified, including silicates,
carbonates, oxides, sulfides, and sulfates. There are literally thousands of naturally formed minerals; some seem rare and exotic because of their color, crystal form, and hardness, and others seem more mundane because they occur as
minor constituents in common rocks. Some we consider precious, such as gold,
silver, diamonds, and rubies; others are important in high technology. In addition to providing documents of Earth’s history, minerals are at the foundation
of all human societies—from pre-Paleolithic times, in which minerals were used
for tools, to modern technological societies that require vast amounts of metals and construction materials.

77

GeoLogic

Internal Structure of Minerals

Gypsum (CaSO4¥2H2O) (1 cm across). Cleavage
planes look like topographic steps

Gypsum seen with scanning tunneling microscope (15 nanometers
across). Individual sulfate ions seen as hills in precise geometric
arrangement. Lighter area is an atom high "plateau," magnified
from the sheets seen in the cleavage planes.

Gypsum seen with scanning electron microscope
(150 microns across). Cleavage planes still visible
as plateaus separating different cleavage sheets.

Gypsum seen with atomic force microscope (10 microns
across). Each cleavage sheet consists of even thinner
layers.

Atomic model of the internal sturctue of gypsum.
Calcium ions (blue) are linked to sulfate groups (sulfur yellow
and oxygen red). Sulfur-oxygen bonds are strong and covalent.
Cleavage planes are created by weak bonds between these tightly
bonded sheets. The layers are bound together by weak hydrogen
bonds. (Hydrogens are small and pink.)

(Images courtesy of Dirk Bosbach and Barry Bickmore )

Seeing is believing—a phrase we often use to discount the
unseeable. But how can we understand the internal structure of minerals at the atomic scale where distances are
measured in nanometers (10-9 m)? These images take you
on a tour through inner space, from the surface of a mineral into its deep interior.
Observations
1. At the lowest magnification with an optical microscope,
you can see the nature of a cleavage plane in gypsum—a
smooth lustrous break.
2. If we zoom in closer with a scanning electron microscope,
you can see that the cleavage plane is not quite as smooth
as it first looked, but you can still see broad flat plateaus.
3. Zooming in closer with an atomic force microscope, we
can see that the planar structure is preserved at the micron
scale (10-6 m). You can see that the mineral grew as a series
of layers controlled by its internal structure. Each “layer”
has a relatively smooth surface but is only a molecule thick.
4. At even higher resolution, the atomic force microscope

78

shows the “smooth surface” is a series of humps and
swales—individual groups of atoms—packed into a precise
geometric network. The “step” shown in brighter colors is
one atomic layer thick and lies on top of other similar layers below it.
Interpretations
The last step of the journey is not a real image, but rather
an interpretive model that has been constructed from the
information gleaned by studying the other images and from
X-ray diffractometry. Each group of atoms is bound together by a strong electrical charge emanating from a cloud
of electrons. This electron cloud gives the atomic groups
their shapes in the images. Finally, the images and measurements show us that the physical properties of a mineral
are controlled by its internal atomic structure. For example, strong bonds form hard minerals and where weak
bonds are aligned like those between the hydrogen ions
shown in the model, the mineral cleaves easily in that
direction.

Minerals

79

KEY TERMS
amorphous solid (p. 57)

crystal form (p. 64)

isotope (p. 56)

plagioclase (p. 72)

amphibole (p.76)

crystallization (p. 67)

liquid (p. 57)

polymorphism (p. 62)

atom (p. 54)

crystal structure (p. 57)

luster (p. 65)

proton (p. 55)

atomic mass (p. 55)

density (p. 65)

mafic mineral (p. 74)

pyroxene (p. 75)

atomic number (p. 55)

dolomite (p. 77)

magnetism (p. 66)

quartz (p. 72)

biotite (p. 74)

electron (p. 55)

melt (p. 68)

recrystallization (p. 69)

calcite (p. 77)

feldspar (p. 72)

metallic bond (p. 57)

silicates (p. 70)

clay mineral (p. 76)

felsic minerals (p. 72)

metastable (p. 66)

cleavage (p. 64)

gas (p. 58)

mica (p. 72)

silicon-oxygen tetrahedron
(p. 70)

color (p. 65)

gypsum (p. 77)

mineral (p. 59)

solid (p. 57)

compound (p. 56)

halite (p. 77)

muscovite (p. 74)

stability range (p. 66)

conchoidal fracture (p. 64)

hardness (p. 65)

neutron (p. 55)

stable (p. 66)

covalent bond (p. 56)

ion (p. 56)

nucleus (p. 54)

streak (p. 66)

crystal (p. 61)

ionic bond (p. 56)

olivine (p. 75)

X-ray diffraction (p. 60)

crystal faces (p. 64)

ionic substitution (p. 62)

oxide mineral (p. 77)

REVIEW QUESTIONS
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.

Contrast atoms, ions, and isotopes.
Give a brief but adequate definition of a mineral.
Explain the meaning of “the internal structure of a mineral.”
Why does a mineral have a definite chemical composition?
What other common element might substitute for Ca in a
plagioclase feldspar? Why?
How do geologists identify minerals too small to be seen in
a hand specimen?
Briefly explain how minerals grow and are destroyed.
Explain the origin of cleavage in minerals.
Describe the silicon-oxygen tetrahedron. Why is it important in the study of minerals?
Discuss the implications of a mineral’s limited stability
range for the kinds of minerals found at progressively
greater depths in Earth’s mantle.

11. Why is color of little use in identifying minerals? What are
some better diagnostic properties?
12. What are silicate minerals? List the silicate minerals that
are most abundant in rocks.
13. Why are feldspars so abundant in Earth’s crust?
14. Construct a table listing the distinguishing characteristics of
quartz, feldspar, biotite, amphibole, pyroxene, mica, and
clay.
15. Study Figure 3.20, and explain why most of the mineral
grains in a granite have an irregular shape even though they
still have an orderly atomic structure.
16. What is the difference between a mineral and a rock?

ADDITIONAL READINGS
Deer, W. A., R. A. Howie, and J. Zussman. 1992. An Introduction to the Rock-Forming Minerals, 2nd ed. New York: Wiley.
Klein, C. 2002. Manual of Mineral Science (after J. D. Dana),
22nd ed. New York: Wiley.
Mackenzie, W. S., and A. E. Adams. 1994. A Color Atlas of Rocks
and Minerals in Thin Section. New York: Halstead Press.
Nesse, W. D. 2000. Introduction to Mineralogy. New York:
Oxford University Press.

Perkins, D. 2001. Mineralogy, 2nd ed. Upper Saddle River, N.J.:
Prentice Hall.
Riciutti, E. R. 1998. National Audubon First Field Guide to
Rocks and Minerals. New York: Scholastic.

MULTIMEDIA TOOLS
Earth’s Dynamic Systems Website
The Companion Website at www.prenhall.com/hamblin
provides you with an on-line study guide and additional resources for each chapter, including:

Earth’s Dynamic Systems CD
Examine the CD that came with your text. It is designed
to help you visualize and thus understand the concepts
in this chapter. It includes:

• On-line Quizzes (Chapter Review, Visualizing Geology,
Quick Review, Vocabulary Flash Cards) with instant feedback

• Animations showing the three-dimensional atomic structures
of common silicate and nonsilicate minerals

• Quantitative Problems

• Video clips of mineral growth

• Critical Thinking Exercises

• A direct link to the Companion Website

• Web Resources

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