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3: Minerals

  • Page ID
    32324
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    Learning Objectives
    • Define mineral.
    • Describe the basic structure of the atom.
    • Derive basic atomic information from the Periodic Table of Elements.
    • Describe chemical bonding related to minerals.
    • Describe the main ways minerals form.
    • Describe the silicon-oxygen tetrahedron and how it forms common silicate minerals.
    • List common non-silicate minerals in oxide, sulfide, sulfate, and carbonate groups.
    • Identify minerals using physical properties and identification tables.
    The crystals are huge!
    Figure \(\PageIndex{1}\): These selenite (gypsum) crystals, found in The Cave of the Crystals in Naica, Mexico, are some of the largest minerals ever found. The largest crystal found here is 39 feet (12 meters) and 55 tons. Note the person for scale. (By Alexander Van Driessche; CC BY 3.0 via Wikimedia Commons.)

    The term “minerals” as used in nutrition labels and pharmaceutical products is not the same as a mineral in a geological sense. In geology, the classic definition of a mineral is:

    1. Naturally occurring
    2. Inorganic
    3. Solid at room temperature
    4. Regular crystal structure
    5. Defined chemical composition

    Some natural substances technically should not be considered minerals, but are included by exception. For example, water and mercury are liquid at room temperature. Both are considered minerals because they were classified before the room-temperature rule was accepted as part of the definition. Calcite is quite often formed by organic processes but is considered a mineral because it is widely found and geologically important. Because of these discrepancies, the International Mineralogical Association in 1985 amended the definition to: “A mineral is an element or chemical compound that is normally crystalline and that has been formed as a result of geological processes.” This means that the calcite in the shell of a clam is not considered a mineral. But once that clamshell undergoes burial, diagenesis, or other geological processes, then the calcite is considered a mineral. Typically, substances like coal, pearl, opal, or obsidian that do not fit the definition of a mineral are called mineraloids.

    A rock is a substance that contains one or more minerals or mineraloids. As is discussed in later chapters, there are three types of rocks composed of minerals: igneous (rocks crystallizing from molten material), sedimentary (rocks made of products of mechanical weathering (sand, gravel, etc.), or chemical weathering (things precipitated from solution)), and metamorphic (rocks produced by alteration of other rocks by heat and pressure).

    • 3.1: Chemistry of Minerals
      Rocks are composed of minerals that have a specific chemical composition. To understand mineral chemistry, it is essential to examine the fundamental unit of all matter, the atom.   Matter is made of atoms. Atoms consist of subatomic particles—protons, neutrons, and electrons. A simple model of the atom has a central nucleus composed of protons, which have positive charges, and neutrons which have no charge. A cloud of negatively charged electrons surrounds the nucleus.
    • 3.2: Formation of Minerals
      Solutions consist of ions or molecules, known as solutes, dissolved in a medium or solvent. In nature, this solvent is usually water. Many minerals can be dissolved in water, such as halite or table salt. The Na+1 and Cl-1 ions separate and disperse into the solution. Precipitation is the reverse process, in which ions in solution come together to form solid minerals. Precipitation is dependent on the concentration of ions in solution and other factors such as temperature and pressure.
    • 3.3: Silicate Minerals
      Minerals are categorized based on their composition and structure. Silicate minerals are built around a molecular ion called the silicon-oxygen tetrahedron. A tetrahedron has a pyramid-like shape with four sides and four corners. Silicate minerals form the largest group of minerals on Earth, comprising the vast majority of the Earth’s mantle and crust. Of the nearly four thousand known minerals on Earth, most are rare.
    • 3.4: Non-Silicate Minerals
      The crystal structure of non-silicate minerals (see table) does not contain silica-oxygen tetrahedra. Many non-silicate minerals are economically important and provide metallic resources such as copper, lead, and iron. They also include valuable non-metallic products such as salt, construction materials, and fertilizer.
    • 3.5: Identifying Minerals
      Geologists identify minerals by their physical properties. In the field, where geologists may have limited access to advanced technology and powerful machines, they can still identify minerals by testing several physical properties: luster and color, streak, hardness, crystal habit, cleavage and fracture, and some special properties. Only a few common minerals make up the majority of Earth’s rocks and are usually seen as small grains in rocks.
    • 3.S: Summary

    Thumbnail: A ball of lustrous, royal-blue cavansite blades is set on a starkly contrasting snow-white crust on basalt matrix on this fine specimen from recent finds at the Wagholi Quarry of India. (CC-SA-BY 3.0; Rob Lavinsky from iRocks.com).


    This page titled 3: Minerals is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Chris Johnson, Matthew D. Affolter, Paul Inkenbrandt, & Cam Mosher (OpenGeology) via source content that was edited to the style and standards of the LibreTexts platform.