Just like in every material, the properties of ceramics are determined by the types of atoms present, the types of bonding between the atoms, and the way the atoms are packed together

Two types of bonds are found in ceramics: ionic and covalent. The ionic bond occurs between a metal and a nonmetal, in other words, two elements with very different electronegativity. Electronegativity is the capability of the nucleus in an atom to attract and retain all the electrons within the atom itself, and depends on the number of electrons and the distance of the electrons in the outer shells from the nucleus.

In an ionic bond, one of the atoms (the metal) transfers electrons to the other atom (the nonmetal), thus becoming positively charged (cation), whereas the nonmetal becomes negatively charged (anion). The two ions having opposite charges attract each other with a strong electrostatic force.

Covalent bonding instead occurs between two nonmetals, in other words two atoms that have similar electronegativity, and involves the sharing of electron pairs between the two atoms.

Although both types of bonds occur between atoms in ceramic materials, in most of them (particularly the oxides) the ionic bond is predominant.

There are two other types of atomic bonds: metallic and the Van der Waals. In the first one, the metal cations are surrounded by electrons that can move freely between atoms. Metallic bonds are not as strong as ionic and covalent bonds. Metallic bonds are responsible for the main properties of metals, such as ductility, where the metal can be easily bent or stretched without breaking, allowing it to be drawn into wire. The free movement of electrons also explains why metals tend to be conductors of electricity and heat.

Van der Waals bonds consist of weak electrostatic forces between atoms that have permanent or induced polarization. An example of Van der Waal bond is the hydrogen bond between hydrogen and oxygen, which is responsible for many properties of water.

In polymers, there are covalent bonds between the atoms of the polymer, but the polymeric macromolecules (or chains) are kept together by Van der Waals forces. Of all the four types of bonds, Van der Waals is the weakest. For this reason, polymers are very elastic (e.g., a rubber band), can be easily melted, and have low strength.

The ionic and covalent bonds of ceramics are responsible for many unique properties of these materials, such as high hardness, high melting points, low thermal expansion, and good chemical resistance, but also for some undesirable characteristics, foremost being brittleness, which leads to fractures unless the material is toughened by reinforcing agents or by other means.

The properties of ceramics, however, also depend on their microstructure. Ceramics are by definition natural or synthetic inorganic, non-metallic, polycrystalline materials. Sometimes, even monocrystalline materials, such as diamond and sapphire, are erroneously included under the term ceramics. Polycrystalline materials are formed by multiple crystal grains joined together during the production process, whereas monocrystalline materials are grown as one three-dimensional crystal. Fabrication processes of polycrystalline materials are relatively inexpensive, when compared to single crystals. Due to these differences (e.g., multiple crystals with various orientations, presence of grain boundaries, fabrication processes), polycrystalline materials should really not be confused with single crystals and should be the only ones included under the definition of ceramics. The properties and the processing of ceramics are largely affected by their grain sizes and shapes, and characteristics such as density, hardness, mechanical strength, and optical properties strongly correlate with the microstructure of the sintered piece.

On the other hand, glass is made of inorganic, non-metallic materials with an amorphous structure. Amorphous structure means that atoms are not organized according to a well-ordered, repeating arrangement as in crystals. Glass-ceramics are made of small grains surrounded by a glassy phase, and have properties in between those of glass and ceramics.

The table below provides a summary of the main properties of ceramics and glass. These are typical properties. In fact, properties of ceramics and glass can be tailored to specific applications by modifying composition, including creating composite materials with metals and polymers, and by changing processing parameters.

Typical properties of ceramics

  • High hardness
  • High elastic modulus
  • Low ductility
  • High dimensional stability
  • Good wear resistance
  • High resistance to corrosion and chemical attack
  • High weather resistance
  • High melting point
  • High working temperature
  • Low thermal expansion
  • Low to medium thermal conductivity
  • Good electrical insulation
  • Low to medium tensile strength
  • High compressive strength
  • Medium machinability
  • Opacity
  • Brittleness
  • Poor impact strength
  • Low thermal shock resistance

Typical properties of glasses

  • High hardness
  • High elastic modulus
  • Low ductility
  • Good dimensional stability
  • Good wear resistance
  • High resistance to chemicals
  • High weather resistance
  • Relatively high melting point
  • Relatively high working temperature
  • Relatively low coefficient of thermal expansion
  • Very low thermal conductivity
  • Good electrical insulation
  • Low tensile strength
  • High compressive strength
  • Poor machinability, but can be blown, drawn or laminated
  • High transparency
  • High brittleness
  • Poor impact strength
  • Low thermal shock resistance