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Hardness:
The hardness of a mineral idicates how
well it resists scratching or abrasion. It is measured on a numerical
scale, from 1 (softest) to 10 (hardest). This scale is called Mohs Scale:
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1
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Talc |
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2
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Gypsum |
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3
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Calcite |
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4
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Fluorite |
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5
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Apatite |
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6
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Orthoclase |
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7
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Quartz |
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8
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Topaz |
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9
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Corundum |
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10
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Diamond |
Streak: The streak of a mineral is its color when it is ground into a fine powder. This may be done by crushing a mineral fragment, placing the powder on a sheet of white paper, and observing the color. A more common (and convenient) procedure is to rub the mineral firmly across a tile of unglazed white porcelain (called a streak plate) to produce a line of powder whose color is called the streak of a mineral. This property may be distinctive when the color of the mineral is different than that of its streak,since the streak varies only slightly from one specimen to another. Streak is most useful for the identifaction of dark colored minerals such as metallic sulfides and oxides; its usefullnes is more limited when testing light colored sulfates, carbonates or silicates. Also, minerals having a hardness exceeding that of the streak plate (About 6 1/2) cannot be tested in this manner.
Luster: The
luster of a mineral is the way its surface reflects light. Luster is governed
largely by the surface characteristics of the mineral's atomic structure
and is slightly modified by its transparency. Luster should not be confused
with color; minerals of different colors may have the same luster. As
with color, the luster of a mineral should be observed on a cleavage surface
or freshly broken, untarnished surface.
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Adamantine |
Brilliant, gemlike luster. |
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Dull |
Descriptive of dull luster. A mineral with a rough, porous, or lusterless surface are described as having a dull or earthy luster. |
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Earthy (luster) |
Descriptive of an earthy luster. A mineral with a rough, porous, or lusterless surface are described as having a dull or earthy luster |
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Greasy |
Descriptive of greasy luster. |
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Metallic |
Containing metal; having the luster of a metallic surface. |
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Nonmetallic |
Containing no metals; describing luster, as non metal like. |
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Oily |
Descriptive of oily luster. |
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Pearly |
Descriptive of pearly luster. |
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Resinous |
Resinlike luster. |
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Silky |
Descriptive of silky luster. |
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Submetallic |
A discretionary term describing luster as falling somewhere in between metallic and nonmetallic. |
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Vitreous |
Glassy luster. |
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Waxy |
Descriptive of waxy luster. |
Cleavage: When a mineral has the tendency to break along one or more smooth, flat lustrous surfaces, it is said to have cleavage. The way the mineral breaks is an indication of the way the atoms are arranged within the crystals. Minerals that break easily and cleanly in one or more directions are said to have perfect cleavage. If the break is less clean the cleavage may be described as good, distinct, poor, or none.
Parting: Not to be confused with cleavage is parting, another physical property that is seen when a crystal is broken. Parting surfaces are smooth and flat, and closely resemble cleavage planes, but they are caused by structural imperfections in the mineral and not by the mineral's atomic structure. These imperfections are usually caused by strains that develop within the mineral crystal as it grows, or they may occur as planes of weakness between twin crystals. One crystal may show parting, while another of the same species may not.
Specific Gravity: The relative weight of any substance is referred to as its specific gravity or simply gravity. The specific gravity of a mineral (or any other substance) is given as a number, comparing its weight with an equal volume of water. Thus, a mineral with a specific gravity of 4 is four times as heavy as water.
Fracture: The
way a mineral fractures can sometimes help to identify it. Most terms
used to describe fracture are listed below.
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Conchoidal |
"Shell-Like," with a smooth curved surface. |
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Earthy (fracture) |
Breaking like clay or chalk |
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Hackly |
Sharp, jagged surfaces like broken metal. |
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Splintery |
Forming elongated splinters (usually applies to fibrous minerals). |
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Uneven |
Rough or irregular surface. |
Tenacity: A mineral's tenacity is its capacity to resist the stress of crushing, tearing, bending, or breaking. Tenacity is usually described by the terms listed below.
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Brittle |
Easily broken by cutting, bending, or hammering. |
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Elastic |
Can be bent (like a spring) and will return to original form when stress is released. |
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Plastic |
Can be bent, but will not return to original form when the stress is released. Also refered to as "Flexible". |
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Malleable |
Can be hammered into thin sheets like gold or copper. |
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Sectile |
Can be cut by a knife into thin shavings. |
Crystal System:
Mineral crystals come in a seemingly infinite range of shapes. But behind
this tremendous diversity of form there is a strict order, because crystals
always grow according to simple mathematical laws. By studying the crystal
geometry, crystallographers can fit any crystal into one of only six basic
crystal systems. These crystal systems are listed below.
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Hexagonal |
Crystals are generally prismatic or columnar, with rounded triangular or hexagonal cross section; characteristic forms are three or six sided prisms, pyramids, and rhombohedrons. The very similar trigonal system is usually included in the hexagonal system. Hexagonal crystals have four axes of symmetry; three, of equal length, lie in a plane at 120 deg.; the fourth axis is longer or shorter and is at right angles to the others. |
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Isometric |
Crystals are generally blocky in appearance or ball-like, with many similar, symmetrical faces; characteristic forms are cubes, octahedrons, and dodecahedrons, either single or in varied combinations. Also called the cubic crystal system. Isometric crystals have three axes of symmetry, all at right angles to one another and all of equal length. |
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Monoclinic |
Crystals are mostly stubby, with tilted, matching faces at opposite ends suggesting a distorted rectangle; characteristic forms are prisms, and pinacoids. Monoclinic crystals have three unequal exes: two axes, at right angles to each other, lie in a plane; the third axis is inclined to the plane of the other two. There is one two-fold axis. |
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Orthorhombic |
Crystals are generally short, stubby, with diamond shaped or rectangular cross section; characteristic forms are four sided prisms, pyramids, and pinacoids (open forms made up of two parallel faces). Orthorhombic crystals have three unequal axes, all at right angles to one another. |
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Tetragonal |
Crystals are often long and slender or even needle-like; characteristic forms are three or six sided prisms, pyramids, and dipyramids. Tetragonal crystals have three axes of symmetry: two axes, of equal length, lie in a plane at 90 deg.; the third is longer or shorter and is at a right angle to the others. |
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Triclinic |
Crystals are usually flattened, with sharp edges and sharp, thin cross section; no right angles on faces or edges; all forms are pinacoids. Triclinic crystals have three axes, all of different length and none perpendicular to the others. |
Crystal Habit:
Each mineral normally takes one or more characteristic forms, which can
be useful in identification. These forms are determined by the manner
of crystal growth and aggregation, and may have little or no resemblance
to the "ideal" shape of the individual crystal. The term "habit"
is used to refer to the minerals preferred mode of growth - that is, to
the arrangement and proportion of the faces on the single crystals. Many
of the commonly used terms for crystal habit are listed below. There are
many others that are fairly self-descriptive.
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Acicular |
Needlelike (e.g. natrolite, stibnite) |
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Bladed |
Broad and flat, elongated like a knife blade (e.g. gypsum). |
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Botryoidal |
Resembling a bunch of grapes; describes hematite and a number of other minerals in which very small radiating crystals are arranged in massive clumps, giving a surface covered with spherical bulges (from Greek botrys, "bunch of grapes"). |
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Dendritic |
Crystallizing in a "tree-like" or branching pattern (e.g. copper). |
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Equant |
Having roughly the same diameter in every direction (e.g. garnet); an equivalent term is equidimensional. |
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Lamellar |
Composed of thin layers, plates, or scales. |
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Massive |
A mineral that occurs either without any definite external crystal form or in poorly defined masses of small crystals. |
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Pisolitic |
Consisting of spherical grains like peas or beans. |
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Prismatic |
Elongated in one direction (e.g. tourmaline). |
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Pseudomorph |
A mineral that has taken the outward crystal form of a different mineral. |
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Striated |
Having very shallow, parallel grooves or depressions on one or more crystal faces (e.g. pyrite). |
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Tabular |
Thick or thin flat plates (e.g. wulfenite). |
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Twin |
A specimen that consists of two or more single crystals of the same mineral, intergrown in a definite systematic arrangement. |