How are Minerals Identified?

Mineralogists are scientists who study minerals. One of the things mineralogists must do is identify and categorize minerals. While a mineralogist might use a high-powered microscope to identify some minerals, most are recognizable using physical properties.
Check out the mineral in the figure below. What is the mineral’s color? What is its shape? Are the individual crystals shiny or dull? Are there lines (striations) running across the minerals?

This mineral has shiny, gold, cubic crystals with striations, so it is pyrite.
The properties used to identify minerals are described in more detail here.

Color, Streak, and Luster

Diamonds are popular gemstones because the way they reflect light makes them very sparkly. Turquoise is prized for its striking greenish-blue color. Specific terms are used to describe the appearance of minerals.


Color is rarely very useful for identifying a mineral. The same mineral can be several different colors. Different minerals may be the same color. Real gold, as seen in Figure below, is very similar in color to the pyrite in Figure above.
Gold nugget.
Gold nugget.

This mineral is shiny, very soft, heavy, and gold in color, and is actually gold.
The same mineral may be found in different colors. Figure below shows a sample of quartz that is colorless and another quartz that is purple. A tiny amount of iron makes quartz purple. Many minerals are colored by chemical impurities.
White and purple quartz.
White and purple quartz.

Purple quartz, known as amethyst, and clear quartz.


Streak is the color of a mineral’s powder. Streak is a more reliable property than color because streak does not vary. Minerals that are the same color may have a different colored streak. Many minerals, such as the quartz above, do not have streak.
To check streak, scrape the mineral across an unglazed porcelain plate (Figure below). Yellow-gold pyrite has a blackish streak, another indicator that pyrite is not gold, which has a golden yellow streak.
Streaking hematite across plate.
Streaking hematite across plate.

The streak of hematite across an unglazed porcelain plate is red-brown.


Luster describes the reflection of light off a mineral’s surface. Mineralogists have special terms to describe luster. One simple way to classify luster is based on whether the mineral is metallic or non-metallic. Minerals, such as pyrite, that are opaque and shiny have a metallic luster. Minerals, such as quartz, have a non-metallic luster. Different non-metallic lusters are described in the Table below.
Six types of non-metallic luster.|| Luster || Appearance ||
Dull, clay-like
Like resins, such as tree sap
Soft-looking with long fibers
Can you match the minerals in the Figure below with the correct luster from the Table above?
Comparison of luster of diamond, quartz, sulfur.
Comparison of luster of diamond, quartz, sulfur.

Diamond has an adamantine luster. Quartz is not sparkly and has a vitreous, or glassy, luster. Sulfur reflects less light than quartz, so it has a resinous luster.

Specific Gravity

Density describes how much matter is in a certain amount of space: density = mass/volume.
Mass is a measure of the amount of matter in an object. The amount of space an object takes up is described by its volume. The density of an object depends on its mass and its volume. For example, the water in a drinking glass has the same density as the water in the same volume of a swimming pool. Gold has a density of about 19 g/cm3; pyrite has a density of about 5 g/cm3 - that’s another way to tell pyrite from gold. Quartz is even less dense than pyrite and has a density of 2.7 g/cm3.
The specific gravity of a substance compares its density to that of water. Substances that are more dense have higher specific gravity.


Hardness is a measure of whether a mineral will scratch or be scratched. Mohs Hardness Scale, shown in the Table below, is a reference for mineral hardness.
Mohs Hardness Scale: 1 (softest) to 10 (hardest).|| Hardness || Mineral ||
(Source:, Adapted by: Rebecca Calhoun, License: Public Domain)
With a Mohs scale, anyone can test an unknown mineral for its hardness. Imagine you have an unknown mineral. You find that it can scratch fluorite or even apatite, but feldspar scratches it. You know that the mineral’s hardness is between 5 and 6. No other mineral can scratch diamond.

Cleavage and Fracture

Breaking a mineral breaks its chemical bonds. Since some bonds are weaker than other bonds, each type of mineral is likely to break where the bonds between the atoms are weaker. So minerals break apart in characteristic ways.
Cleavage is the tendency of a mineral to break along certain planes to make smooth surfaces. Halite breaks between layers of sodium and chlorine to form cubes with smooth surfaces (Figure below).
A close-up view of sodium chloride in a water bubble aboard the International Space Station.
A close-up view of sodium chloride in a water bubble aboard the International Space Station.

A close-up view of sodium chloride in a water bubble aboard the International Space Station.
Mica has cleavage in one direction and forms sheets (Figure below).
Sheets of mica.
Sheets of mica.

Sheets of mica.
Minerals can cleave into polygons. Fluorite forms octahedrons (Figure below).
Fluorite has octahedral cleavage.
Fluorite has octahedral cleavage.

Fluorite has octahedral cleavage.
One reason gemstones are beautiful is that the cleavage planes make an attractive crystal shape with smooth faces.
Fracture is a break in a mineral that is not along a cleavage plane. Fracture is not always the same in the same mineral because fracture is not determined by the structure of the mineral (Figure below).
Minerals may have characteristic fractures. Metals usually fracture into jagged edges. If a mineral splinters like wood it may be fibrous. Some minerals, such as quartz, form smooth curved surfaces when they fracture.
Chrysotile has splintery fracture.
Chrysotile has splintery fracture.

Chrysotile has splintery fracture.

Other Identifying Characteristics

Some minerals have other unique properties, some of which are listed in the Table below. Can you name a unique property that would allow you to instantly identify a mineral that’s been described quite a bit in this chapter? (Hint: It is most likely found on your dinner table.)
Some minerals have unusual properties that can be used for identification.|| Property || Description || Example of Mineral ||
Mineral glows under ultraviolet light
Mineral is attracted to a magnet
Mineral gives off radiation that can be measured with Geiger counter
Bubbles form when mineral is exposed to a weak acid
Some minerals have a distinctive smell
Sulfur (smells like rotten eggs)
Some minerals taste salty
(Adapted by: Rebecca Calhoun, License: CC-BY-SA)
A simple lesson on how to identify minerals is seen in this video:

Lesson Summary

  • Minerals have distinctive properties that can be used to help identify them.
  • Color and luster describe the mineral’s outer appearance. Streak is the color of the powder.
  • A mineral has a characteristic density.
  • Mohs Hardness Scale is used to compare the hardness of minerals.
  • Cleavage or the characteristic way a mineral breaks depends on the crystal structure of the mineral.
  • Some minerals have special properties that can be used to help identify them.

Review Questions

  1. Which properties of a mineral describe the way it breaks apart?
  2. A mineral looks dry and chalky. What sort of luster does it have?
  3. What causes a mineral to have the properties that it has?
  4. Apatite scratches the surface of an unknown mineral. Which mineral would you use next to test the mineral’s hardness—fluorite or feldspar? Explain your reasoning.
  5. Why is streak more reliable than color when identifying a mineral?
  6. Mineral A has a density of 5 g/cm3. Mineral B is twice as dense as Mineral A. What is the density of Mineral B?
  7. Why do some minerals cleave along certain planes?

Further Reading / Supplemental Links


streak The color of the powder of a mineral. mineralogist A scientist who study minerals. luster The way light reflects off of the surface of the mineral. hardness The ability of a mineral to resist scratching. fracture The way a mineral breaks when it is not broken along a cleavage plane. density The amount of matter in a certain amount of space; mass divided by volume. cleavage The tendency of a mineral to break along certain planes to make smooth surfaces.

Points to Consider

  • If a mineral is magnetic, do you know for certain what mineral it is?
  • Some minerals are colored because they contain chemical impurities. How did the impurities get into the mineral?
  • What two properties of a mineral sample would you have to measure to calculate its density?
  • How much do minerals reflect the environment in which they formed?