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Ceramics
Ceramic Definition and Chemistry
Understand What
Ceramics Are in Chemistry
by Anne Marie
Helmenstine, Ph.D.
The word "ceramic" comes from the Greek word
"keramikos", which means "of pottery".
While the earliest ceramics were pottery, the term encompasses a
large group of materials, including some pure elements.
A ceramic is an inorganic,
nonmetallic solid,
generally based on an oxide, nitride, boride, or carbide, that is fired at a
high temperature.
Ceramics may be glazed prior to firing to produce a coating that
reduces porosity and has a smooth, often colored surface.
Many ceramics contain a mixture of ionic and covalent bonds
between atoms. The resulting material may be crystalline, semi-crystalline, or
vitreous.
Amorphous materials with similar composition are generally
termed "glass".
The four main types of ceramics are whitewares, structural
ceramics, technical ceramics, and refractories.
Whitewares include cookware, pottery, and wall tiles.
Structural ceramics include bricks, pipes, roofing tiles, and
floor tiles.
Technical ceramics are also known as special, fine, advanced, or
engineered ceramics. This class includes bearings, special tiles (e.g.
spacecraft heat shielding), biomedical implants, ceramic brakes, nuclear fuels,
ceramic engines, and ceramic coatings.
Refractories are ceramics used to make crucibles, line kilns,
and radiate heat in gas fireplaces.
How Ceramics Are Made
Raw materials for ceramics include clay, kaolinate, aluminum
oxide, silicon carbide, tungsten carbide, and certain pure elements.
The raw materials are combined with water to form a mix that can
be shaped or molded.
Ceramics are difficult to work after they are made, so usually
they are shaped into their final desired forms. The form is allowed to dry and
is fired in an oven called a kiln.
The firing process supplies the energy to form new chemical
bonds in the material (vitrification) and sometimes new minerals (e.g., mullite
forms from kaolin in the firing of porcelain).
Waterproof, decorative, or functional glazes may be added prior
to the first firing or may require a subsequent firing (more common).
The first firing of a ceramic yields a product called the bisque. The first firing burns off organics and other
volatile impurities.
The second (or third) firing may be called glazing.
Examples and Uses of
Ceramics
Pottery, bricks, tiles, earthenware, china, and porcelain are
common examples of ceramics.
These materials are well-known for use in building, crafting,
and art. There are many other ceramic materials:
· In the past, glass was considered a ceramic, because it's an
inorganic solid that is fired and treated much like a ceramic. However, because
glass is an amorphous solid,
glass is usually considered to be a separate material. The ordered internal
structure of ceramics plays a large role in their properties.
· Solid pure silicon and carbon may be considered to be ceramics.
In a strict sense, a diamond could
be called a ceramic.
· Silicon carbide and tungsten carbide are technical ceramics that
have high abrasion resistance, making them useful for body armor, wear plates
for mining, and machine components.
· Uranium oxide (UO2 is
a ceramic used as a nuclear reactor fuel.
· Zirconia (zirconium
dioxide) is used to make ceramic knife blades, gems, fuel cells, and oxygen
sensors.
· Zinc oxide (ZnO) is a semiconductor.
· Boron oxide is used to make body armor.
· Bismuth strontium copper oxide and magnesium diboride (MgB2) are
superconductors.
· Steatite (magnesium silicate) is used as an electrical
insulator.
· Barium titanate is used to make heating elements, capacitors,
transducers, and data storage elements.
· Ceramic artifacts are useful in archaeology and paleontology
because their chemical composition can be used to identify their origin. This
includes not only the composition of clay, but also that of the temper -- the materials added during production
and drying.
Properties of Ceramics
Ceramics include such a wide variety of materials that it's
difficult to generalize their characteristics. Most ceramics exhibit the
following properties:
·
High hardness
·
Usually brittle, with poor toughness
·
High melting point
·
Chemical resistance
·
Poor electrical and thermal conductivity
·
Low ductility
·
High modulus of elasticity
·
High compression strength
·
Optical transparency to a variety of wavelengths
Exceptions include superconducting and piezoelectric ceramics.
Related Terms
The science of the preparation and characterization of ceramics
is called ceramography.
Composite materials are made up of more than one class of
material, which may include ceramics. Examples of composites include carbon
fiber and fiberglass. A cermet is a
type of composite material containing ceramic and metal.
A glass-ceramic is a
noncrystalline material with a ceramic composition. While crystalline ceramics
tend to be molded, glass-ceramics form from casting or blowing a melt.
Examples of glass-ceramics include "glass" stove tops
and the glass composite used to bind nuclear waste for disposal.
Anne
Marie Helmenstine, Ph.D.
Introduction
Ph.D. in
biomedical sciences from the University of Tennessee at Knoxville - Oak Ridge
National Laboratory.
Science
educator with experience teaching chemistry, biology, astronomy, and
physics at the high school, college, and graduate levels.
ThoughtCo
and About Education chemistry expert since 2001.
Widely-published
graphic artist, responsible for printable periodic tables and other
illustrations used in science.
Experience
Anne
Helmenstine, Ph.D. has covered chemistry for ThoughtCo and About Education
since 2001, and other sciences since 2013. She taught chemistry, biology,
astronomy, and physics at the high school, college, and graduate levels.
She has worked as a research scientist and also abstracting and indexing
diverse scientific literature for the Department of Energy.
In
addition to her work as a science writer, Dr. Helmenstine currently serves as a
scientific consultant, specializing in problems requiring an interdisciplinary
approach. Previously, she worked as a research scientist and college professor.
Education
Dr.
Helmenstine holds a Ph.D. in biomedical sciences from the University of
Tennessee at Knoxville and a B.A. in physics and mathematics with a minor
in chemistry from Hastings College. In her doctoral work, Dr. Helmenstine
developed ultra-sensitive chemical detection and medical diagnostic tests.
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and Dotdash
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