Rocks and Minerals

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Silver

Soft white metal and usually occurs as a minor constituent in the ores of other metals. Is a precious metal due to its rarity and economic value. Electrical and thermal conductance that is higher than any other metal. Higher reflectivity at most temperatures than any other metal, attractive color and luster that resist tarnish and make the metal desirable in jewelry, coins, tableware, etc. Family: Native Formula: Ag Color: silvery white Habit: thin flakes, paltes, and dendritic crystal clusters formed in the narrow spaces of joints and fractures. filiform and wire like habits are also seen. Crystal system: isometric Streak: silvery white Luster: metallic Crystal Structure: Cleavage: none Fracture: Tenacity: Hardness: 2.5 - 3 SG: 10-11 Diaphaneity: opaque Formation: Other: Rarely found as a native element mineral. rarely found in significant amounts in placer deposits. Native sometimes found in the oxidized zones avoce the ores of other metals. Silver does not readily reacnt with oxygen or water, reacts with hydrogen sulfide to produce a tarnished surface that is composed of acantite. Most native silver found associated with hydrothermal activity, often occurs in abudafce as veins and cavity fillings. Most gold found in placer deposits is alloyed with small amounts of silver. If the ratio between gold and silver reaches at least 20% silver, the material is called "electrum." Electrum is the name for an alloy of gold and silver. A significant amount of today's silver production is a refining byproduct of gold mining. Most of the silver produced today is a byproduct of mining copper, lead, and zinc. The silver occurs within the ores of these metals in one of two ways: 1) substituting for one of the metal ions within the ore mineral's atomic structure; or, 2) occurring as an inclusion of native silver or a silver mineral within the ore mineral. The value of this minor silver within the ore mineral can exceed the value of the primary metal within the ore. Uses in jewelry, tableware, coins, electronics, photographic films, ornaments

Hematite

The most important ore of iron. Pigment, heavy media separation, radiation shielding, ballast, polishing compounds, a minor gemstone. Common rock-forming mineral found in sedimentary, metamorphic, and igneous rocks. Despite variable appearance always has a reddish streak. Family: Oxide Formula: Fe2O3 Color: Black to steel-gray to silver; red to reddish brown to black Habit: micaceous, massive, crystalline, botryoidal, fibrous, oolitic, and others. Crystal system: Trigonal Streak: Red to reddish brown Luster: metallic, submetallic, earthy Crystal Structure: Cleavage: none Fracture: Tenacity: Hardness: 5-6.5 SG: 5-5.3 Diaphaneity: opaque Formation: Pure hematite has a composition of about 70% iron and 30% oxygen by weight. Like most natural materials, it is rarely found with that pure composition. This is particularly true of the sedimentary deposits where hematite forms by inorganic or biological precipitation in a body of water. primary mineral and as an alteration product in igneous, metamorphic, and sedimentary rocks. It can crystallize during the differentiation of a magma or precipitate from hydrothermal fluids moving through a rock mass. It can also form during contact metamorphism when hot magmas react with adjacent rocks. The most important hematite deposits formed in sedimentary environments. About 2.4 billion years ago, Earth's oceans were rich in dissolved iron, but very little free oxygen was present in the water. Then a group of cyanobacteria became capable of photosynthesis. The bacteria used sunlight as an energy source to convert carbon dioxide and water into carbohydrates, oxygen, and water. This reaction released the first free oxygen into the ocean environment. The new oxygen immediately combined with the iron to form hematite, which sank to the bottom of the seafloor and became the rock units that we know today as the banded iron formations. Soon, photosynthesis was occurring in many parts of Earth's oceans, and extensive hematite deposits were accumulating on the seafloor. This deposition continued for hundreds of millions of years - from about 2.4 to 1.8 million years ago. This allowed the formation of iron deposits hundreds to several thousand feet thick that are laterally persistent over hundreds to thousands of square miles. They comprise some of the largest rock formations in Earth's rock record. Other: By itself is not magnetic but if it contains enough magnetite then it may seem that way. Many of the sedimentary iron deposits contain both hematite and magnetite as well as other iron minerals. These are often in intimate association, and the ore is mined, crushed, and processed to recover both minerals.Minor clastic sedimentation can add clay minerals to the iron oxide. Episodic sedimentation can cause the deposit to have alternating bands of iron oxide and shale. Silica in the form of jasper, chert, or chalcedony can be added by chemical, clastic, or biological processes in small amounts or in significant episodes. These layered deposits of hematite and shale or hematite and silica have become known as the "banded iron formations" (see image). Hematite is one of the most abundant minerals in the rocks and soils on the surface of Mars, gives the landscape a reddish-brown color.

Dolomite

Thin, platy cream-colored crystals possibly has black specks between crystals. Differentiate from calcite using hardness and reaction to acid. Family: Carbonate Formula: CaMg(CO3)2 Color: White, grey to pink, reddish-white, brownish-white; colorless in transmitted light, Small amounts of iron in the structure give the crystals a yellow to brown tint. Manganese substitutes in the structure also up to about three percent MnO. A high manganese content gives the crystals a rosy pink color. Habit: Tabular crystals, often with curved faces, also columnar, stalactitic, granular, massive Crystal system: Trigonal Streak: White Luster: Vitreous to pearly Crystal Structure: Cleavage: 3 directions of cleavage not at right angles Fracture: conchoidal Tenacity: brittle Hardness: 3.5-4 SG: 2.84-2.86 Diaphaneity: transparent to translucnet Formation: found to occur under anaerobic conditions in supersaturated saline lagoons Other: Lead, zinc, and cobalt also substitute in the structure for magnesium. Used for acid neutralization in the chemical industry, in stream restoration projects, and as a soil conditioner. Dolomite is used as a source of magnesia (MgO), a feed additive for livestock, a sintering agent and flux in metal processing, and as an ingredient in the production of glass, bricks, and ceramics. Dolomite serves as the host rock for many lead, zinc, and copper deposits. These deposits form when hot, acidic hydrothermal solutions move upward from depth through a fracture system that encounters a dolomitic rock unit. These solutions react with the dolomite, which causes a drop in pH that triggers the precipitation of metals from solution. Dolomite also serves as an oil and gas reservoir rock. During the conversion of calcite to dolomite, a volume reduction occurs. This can produce pore spaces in the rock that can be filled with oil or natural gas that migrate in as they are released from other rock units. This makes the dolomite a reservoir rock and a target of oil and gas drilling.

Aventurine

a form of quartz, characterised by its translucency and the presence of platy mineral inclusions that give it a shimmering or glistening effect termed aventurescence. Family: Silicate Formula: SiO2 Color: Usually green. Also orange, yellow, red, pink, purple, white, brown, and blue. Habit: Crystal system: hexagonal Streak: colorless Luster: vitreous, aventuresecnt Cleavage: Fracture: Tenacity: Hardness: 6.5-7 SG: 2.6-2.7 Diaphaneity: Formation: Other: most common color of aventurine is green, but it may also be orange, brown, yellow, blue, or grey. Chrome-bearing fuchsite (a variety of muscovite mica) is the classic inclusion and gives a silvery green or blue sheen. Oranges and browns are attributed to hematite or goethite Green aventurine is a common material used to produce beads and cabochons. These are used to make earrings, pendants, rings, and other jewelry. Aventurine and translucent quartz without aventurescence are often dyed bright colors. Dye is used to produce low-cost cabochons with bright colors that are often seen in inexpensive jewelry.

Pyromorphite

a member of the Apatite group, a group of isomorphous hexagonal minerals. It is very similar in structure and appearance to Mimetite, and may be partially replaced by it. In fact, sometimes Pyromorphite and Mimetite are virtually indistinguishable from each other and may be wrongly labeled as the other. It is part of a series with two other minerals: mimetite (Pb5(AsO4)3Cl) and vanadinite (Pb5(VO4)3Cl), the resemblance in external characters is so close that, as a rule, it is only possible to distinguish between them by chemical tests. They were formerly confused under the names green lead ore and brown lead ore. The name is derived from the Greek for pyr (fire) and morfe (form) due to its crystallization behavior after being melted. Family: Phosphate, Apatite group Formula: Pb5(PO4)3Cl Color: Dark green to grass-green or green, yellow, yellow-orange, reddish orange, yellow-brown, greenish-yellow or yellowish-green, shades of brown, tan, grayish, white and may be colorless; colourless or faintly tinted in transmitted light Habit: prismatic to acicular crystals, globular to reniform . Occurs as barrel-like hexagonal crystals, which are usually grouped together in interesting aggregates, and may be bipyramidal. Also acicular, crusty, grainy, radiating, reniform, botryoidal and in curvy aggregates. Some larger crystals may be hollowed out on the ends or have a hopper growth pattern.Crystal system: hexagonal Streak: white Luster: resinous to subadamantine Cleavage: imperfect Fracture: uneven to sub conchoidal Tenacity: brittle Hardness: 3.5-4 SG: 7.04 measured, 7.14 calculated Diaphaneity: transparent to translucent Formation: As a secondary mineral in the oxidation zone of lead ore deposits. Other: Dissolves in nitric acid. Pyromorphite is a minor ore of lead where it occurs with more abundant lead minerals. It is also a popular mineral among collectors, especially specimens from classic occurrences, as well as newer finds of bright neon green Pyromorphite which command very high prices.

Pyrite

"Fool's Gold." The mineral's gold color, metallic luster, and high specific gravity often cause it to be mistaken for gold by inexperienced prospectors. However, pyrite is often associated with gold. The two minerals often form together, and in some deposits pyrite contains enough included gold to warrant mining. Family: sulfide Formula: FeS2 Color: Brass yellow - often tarnished to brass Habit: Crystal system: isometric Streak: greenish black to brownish black Luster: metallic Cleavage: breaks with a conchoidal fracture Fracture: Tenacity: Hardness: 6-6.5 SG: 4.9-5.2 Diaphaneity: opaque Formation: most common sulfide mineral. It forms at high and low temperatures and occurs, usually in small quantities, in igneous, metamorphic, and sedimentary rocks worldwide. Pyrite is so common that many geologists would consider it to be a ubiquitous mineral. Other: The name "pyrite" is after the Greek "pyr" meaning "fire." This name was given because pyrite can be used to create the sparks needed for starting a fire if it is struck against metal or another hard material. Pieces of pyrite have also been used as a spark-producing material in flintlock firearms. Pyrite used to be an important ore for the production of sulfur and sulfuric acid. Today most sulfur is obtained as a byproduct of oil and gas processing. Some sulfur continues to be produced from pyrite as a byproduct of gold production. The most important use of pyrite is as an ore of gold. Gold and pyrite form under similar conditions and occur together in the same rocks. In some deposits small amounts of gold occur as inclusions and substitutions within pyrite. Crushed stone used to make concrete, concrete block, and asphalt paving materials must be free of pyrite. Pyrite will oxidize when it is exposed to air and moisture. That oxidation will result in the production of acids and a volume change that will damage the concrete and reduce its strength. This damage can result in failure or maintenance problems. The conditions of pyrite formation in the sedimentary environment include a supply of iron, a supply of sulfur, and an oxygen-poor environment. This often occurs in association with decaying organic materials. Organic decay consumes oxygen and releases sulfur. For this reason, pyrite commonly and preferentially occurs in dark-colored organic-rich sediments such as coal and black shale. The pyrite often replaces organic materials such as plant debris and shells to create interesting fossils composed of pyrite.

Beryl

a minor ore of beryllium, and color varieties of the mineral are among the world's most popular gemstones. Emerald, aquamarine, heliodor, and morganite are the most popular varieties Family: Silicate Formula: Be3Al2Si6O18 Color: Green, yellow, blue, red, pink, orange, colorless Habit: Crystal system: Hexagonal Streak: colorlesss Luster: vitreous Cleavage: imperfect Fracture: Tenacity: Hardness: 7.5-8 SG: 2.6-2.8 Diaphaneity: transparent to translucent Formation: contains a significant amount of beryllium. Beryllium is a very rare metal, and that limits the formation of beryl to a few geological situations where beryllium is present in sufficient amounts to form minerals. It mainly occurs in granite, rhyolite, and granite pegmatites; in metamorphic rocks associated with pegmatites; and, in veins and cavities where hydrothermal activity has altered rocks of granitic composition. These different types of deposits are often found together and serve as an exploration indicator for finding beryl. Beryl is also found where carbonaceous shale, limestone, and marble have been acted upon by regional metamorphism. The famous emerald deposits of Colombia and Zambia were formed under these conditions. The carbonaceous material is thought to provide the chromium or vanadium needed to color the emerald. Other: Beryl once served as the world's only important ore of beryllium metal. But in 1969, Spor Mountain, Utah became the source for about 80% of the world's beryllium supply when bertrandite, a beryllium silicate hydroxide mineral, was discovered there. The extraction of beryllium from beryl is very costly, and as long as bertrandite is available in large amounts, beryl will remain a minor ore of that metal. Small amounts of beryl, mostly produced as a by-product of gemstone mining, are still used to produce beryllium. The most important use of beryl today is as a gemstone. It is one of the most important gem minerals, and the gems of beryl are named by their color as: emerald (green), aquamarine (greenish blue to blue), morganite (pink to orange), red beryl (red), heliodor (yellow to greenish yellow), maxixe (deep blue), goshenite (colorless), and green beryl (light green). Synthetic beryl has been commercially manufactured for gemstone use since the 1930s. Synthetic beryls have the same chemical composition and physical properties as natural beryl. They can be fashioned into gemstones that rival the beauty of natural gems and can be sold for a much lower cost. Many people opt for a synthetic emerald because it can have a superior color, superior clarity, greater durability, and a much lower cost than a natural gem.

Agate

Agate is one of the most common materials used in the art of hardstone carving, and has been recovered at a number of ancient sites, Family: Silicate Formula: SiO2 Color: brown, white, red, gray, pink, black, and yellow. The colors are caused by impurities and occur as alternating bands within the agate. The different colors were produced as groundwaters of different compositions seeped into the cavity. The banding within a cavity is a record of water chemistry change. This banding gives many agates the interesting colors and patterns that make it a popular gemstone Habit: Crystal system: Streak: white Luster: waxy, dull Cleavage: none Fracture: conchoidal, subschoncoidal Tenacity: brittle Hardness: 6.5-7 SG: 2.6 Diaphaneity: Formation: generally forms by the deposition of silica from groundwater in the cavities of igneous rocks. The agate deposits in concentric layers around the walls of the cavity, or in horizontal layers building up from the bottom of the cavity. These structures produce the banded patterns that are characteristic of many agates. Some of these cavities are lined with crystals and those are known as geodes. Other: Lace agate is a variety that exhibits a lace-like pattern with forms such as eyes, swirls, bands or zigzags. Moss agate, as the name suggests, exhibits a moss-like pattern and is of a greenish colour. The coloration is not created by any vegetative growth, but rather through the mixture of chalcedony and oxidized iron hornblende. Dendritic agate also displays vegetative features, including fern-like patterns formed due to the presence of manganese and iron oxides.[14] Turritella agate (Elimia tenera) is formed from the shells of fossilized freshwater Turritellas, gastropods with elongated spiral shells. Similarly, coral, petrified wood, porous rocks and other organic remains can also form agate.[15] Coldwater agates, such as the Lake Michigan cloud agate, did not form under volcanic processes, but instead formed within the limestone and dolomite strata of marine origin. Like volcanic-origin agates, Coldwater agates formed from silica gels that lined pockets and seams within the bedrock. These agates are typically less colorful, with banded lines of grey and white chalcedony.[16] Greek agate is a name given to pale white to tan colored agate found in Sicily, once a Greek colony, back to[clarification needed] 400 BC. The Greeks used it for making jewelry and beads. Brazilian agate is found as sizable geodes of layered nodules. These occur in brownish tones inter-layered with white and gray. Quartz forms within these nodules, creating a striking specimen when cut opposite the layered growth axis. It is often dyed in various colors for ornamental purposes. Polyhedroid agate forms in a flat-sided shape similar to a polyhedron. When sliced, it often shows a characteristic layering of concentric polygons. It has been suggested that growth is not crystallographically controlled but is due to the filling-in of spaces between pre-existing crystals which have since dissolved.

Ulexite

Almost always white, and looks like a densely-packed bundle of white threads. It's opaque in one direction, and conducts light in the other. It's fiber-optic abilities gave it the nickname "T.V. rock". Family: Borate Formula: NaCaB5O6(OH)6·5H2O Color: Colorless to white Habit: Acicular to fibrous Crystal system: triclinic Streak: White Luster: vitreous; silky or satiny in fibrous aggregates Cleavage: ADD Fracture: Uneven Tenacity: Brittle Hardness: 2.5 SG: 1.95-1.96 Diaphaneity: Transparent to opaque Formation: Found in evaporite deposits and looks like a cotton ball tuft of acicular crystals. Found in CA and NV Other: Mined for the boron in it

Apophyllite

a specific group of phyllosilicates, a class of minerals. includes the members fluorapophyllite-(K), fluorapophyllite-(Na), hydroxyapophyllite-(K). derived from the Greek apophylliso, meaning "it flakes off", a reference to this class's tendency to flake apart when heated, due to water loss. Exfoliation of apophyllite is also possible by treating it with acids or simply by rubbing it. Family: Silicate Formula: (K,Na)Ca4Si8O20(F,OH)·8H2O Color: Usually white, colorless; also blue, green, brown, yellow, pink, violet Habit: Prismatic, tabular, massive Crystal system: P4/mnc (no. 128) Streak: white Luster: vitreous; pearly Cleavage: Fracture: uneven Tenacity: Hardness: 4.5 - 5 SG: 2.3 - 2.4 Diaphaneity: transparent to translucent Formation: typically found as secondary minerals in vesicles in basalt or other volcanic rocks. Other: Whereas most phyllosilicates have a T layer (silica backbone) consisting of interlocked 6-fold rings of silica tetrahedra, with pseudohexagonal symmetry, the T layer in apophyllite consists of interlocked 4-fold and 8-fold rings of silica tetrahedra with true tetragonal symmetry

Celestite

Also called celestine. The mineral is named for its occasional delicate blue color. Is one of the principal sources of the element strontium, commonly used in fireworks and in various metal alloys. Family: Sulfate Formula: SrSO4 Color: White, Pink, Pale green, Pale brown, Black, Pale blue, Reddish, Greyish; Colourless or lightly tinted in transmitted light Habit: Tabular to pyramidal crystals, also fibrous, lamellar, earthy, massive granular Crystal system: orthorhombic Streak: white Luster: vitreous, pearly on cleavages Cleavage: Fracture: uneven Tenacity: brittle Hardness: 3-3.5 SG: 3.95-3.97 Diaphaneity: transparent to translucent Formation: mostly found in sedimentary rocks, often associated with the minerals gypsum, anhydrite, and halite. In carbonate marine sediments, burial dissolution is a recognized mechanism of celestine precipitation. It is sometimes used as a gemstone. Celestine crystals are found in some geodes. Celestine geodes are understood to form by the replacement of alabaster nodules consisting of the calcium sulfates gypsum or anhydrite. Calcium sulfate is sparingly soluble, but strontium sulfate is mostly insoluble. Strontium-bearing solutions that come into contact with calcium sulfate nodules dissolve the calcium away, leaving a cavity. The strontium is immediately precipitated as celestine, with the crystals growing into the newly-formed cavity. Other: The world's largest known geode, a celestine geode 35 feet (11 m) in diameter at its widest point, is located near the village of Put-in-Bay, Ohio, on South Bass Island in Lake Erie.

Citrine

a transparent variety of quartz with a yellow to orange color. Its attractive color, high clarity, low price, and durability make it the most frequently purchased yellow to orange gem. Family: Silicate Formula: SiO2 Color: pale yellow to brown Habit: 6-sided prism ending in 6-sided pyramid (typical), drusy, fine-grained to microcrystalline, massive Crystal system: Streak: white Luster: vitreous Cleavage: Fracture: conchoidal Tenacity: Hardness: 7 SG: 2.65 Diaphaneity: translucent Formation: Color due to a submicroscopic distribution of colloidal ferric hydroxide impurities Other: Reddish orange and reddish brown are rare colors in quartz. Gems of these reddish colors are often called Madeira citrine. Citrine and topaz are both available in the yellow to orange color range, but citrine generally has a much lower cost. 1. citrine with a natural color2. citrine with a natural color, but enhanced by treatment3. citrine produced by heating light amethyst4. synthetic citrine (a man-made product)5. imitation citrine (a man-made product that is not SiO2)

Halite

Also known as "salt". Most is crushed and used in the winter on roads to control the accumulation of snow and ice. Significant amounts are also used by the chemical industry. An essential nutrient for humans and most animals, and it is also a favorite seasoning for many types of food. Family: Halide Formula: NaCl Color: Colorless or white when pure; impurities produce any color but usually yellow, gray, black, brown, red Habit: Predominantly cubes and in massive sedimentary beds, but also granular, fibrous and compact Crystal system: isometric/cubic Streak: White Luster: Vitreous Crystal Structure: Cleavage: perfect, cubic, three directions at right angles Fracture: conchoidal Tenacity: brittle Hardness: 2.5 SG: 2 Diaphaneity: transparent to translucent Formation: mainly a sedimentary mineral that usually forms in arid climates where ocean water evaporates. However, many inland lakes such as the Great Salt Lake of North America and the Dead Sea between Jordan and Israel are also locations where halite is forming today. Over geologic time, several enormous salt deposits have been formed when repeated episodes of seawater evaporation occurred in restricted basins. Some of these deposits are thousands of feet thick. When buried deeply they can erupt to form salt domes. Other:

Corundum

Defining mineral for 9 in MHS. Rock-forming mineral that is found in igneous, metamorphic, and sedimentary rocks. Hexagonal crystal structure. Extreme hardness and sometimes found as beautiful transparent crystals found in many different colors. Excellent abrasive and the different colors are ruby and sapphire. Family: Oxide Formula: Al2O3 Color: Typically gray to brown. Colorless when pure, but trace amounts of various metals produce almost any color. Chromium produces red (ruby) and combinations of iron and titanium produce blue (sapphire). Habit: Steep bipyramidal, tabular, prismatic, rhombohedral crystals, massive or granular Crystal system: Trigonal Streak: colorless, harder than streak plate. white Luster: adamantine to vitreous Crystal Structure: Cleavage: none Fracture: conchoidal to uneven Tenacity: Brittle Hardness: 9 defining mineral SG: 3.9-4.1 Diaphaneity: transparent to translucent Formation: Some of the world's most important ruby and sapphire deposits are found where the gems have weathered from basalt flows and are now found in the downslope soils and sediments. Corundum is also found in metamorphic rocks in locations where aluminous shales or bauxites have been exposed to contact metamorphism. Corundum's toughness, high hardness, and chemical resistance enable it to persist in sediments long after other minerals have been destroyed. This is why it is often found concentrated in alluvial deposits. Synthetic version produced using calcined bauxite and has more reliable properties suited for industrial properties. Other: Most people are familiar with corundum; however, very few people know it by its mineral name - instead they know it by the names "ruby" and "sapphire." A gemstone-quality specimen of corundum with a deep red color is known as a "ruby." A gemstone-quality corundum with a blue color is called a "sapphire." Colorless corundum is known as "white sapphire." Corundum of any other color is known as "fancy sapphire." High demand of rubys and sapphies leads to increase use of synthetic versions. In the mid-1800s, watch makers in Switzerland needed tiny bearings that were highly resistant to abrasion, used corundum called "jewel bearings". Synthetic ones eventually replace. Colorless synthetic sapphire is used for covering for the face of watches. Synthetic corundum is an essential part of many lasers. In fact, the first working laser was a "ruby laser," made by Theodore Maiman at Hughes Research Labs in 1960. chemically inert and resistant to heat. These properties make it a perfect material for making refractory products such as fire brick, kiln liners, and kiln furniture. Today, these products are usually made with synthetic corundum. Pure corundum is colorless, transparent, durable, and scratch resistant. Large crystals of clear synthetic corundum are grown, sawn into thin sheets, and then used as the windows of grocery store scanners, watch crystals, aircraft windows, and protective covers for electronic devices.

Actinolite

Derived from the Greek word aktis (ἀκτίς), meaning "beam" or "ray", because of the mineral's fibrous nature. intermediate member in a solid-solution series between magnesium-rich tremolite and iron rich ferro actinolite. Family: Silicate Formula: Ca2(Mg4.5-2.5Fe2+0.5-2.5)Si8O22(OH)2 Color: pale to dark green, yellowish green and black. White or grey when in asbestos Habit: bladed, fibrous, radial Crystal system: monoclinic Streak: white Luster: vitreous to dull Cleavage: perfect along one axis Fracture: uneven Tenacity: Hardness: 5-6 SG: 3 Diaphaneity: translucent to transparent Formation: commonly found in metamorphic rocks, such as contact aureoles surrounding cooled intrusive igneous rocks. It also occurs as a product of metamorphism of magnesium-rich limestones Other: Some forms of actinolite are used as gemstones. One is nephrite, one of the two types of jade

Diamond

Each carbon is surrounded by four other carbons ad connected by strong covalent bonds. The strongest known natural substance. Chemically resistant and has the highest thermal conductivity of any natural material. A high index of refraction, high dispersion, adamantine luster. World's most popular gemstone, used in specialty lenses requiring durability and performance. Family: Native Formula: C Color: most brown or yellow, jewelry favors colorless. those in hies of red, orange, green, blue, pink, purple, violet, and yellow are extremely rare. Habit: octahedral Crystal system: isometric Streak: none or colorless, harder than a streak plate, Luster: adamantine Crystal Structure: Cleavage: perfect octahedral cleavage in 4 directions Fracture: uneven Tenacity: Hardness: 10, hardest known mineral, hardest parallel to octahedral planes, softest parallel to its cubic planes SG: 3.4-3.6 Diaphaneity: transparent, translucent, opaque Formation: Form at high temperatures and pressures that occur in the earth's mantle about 100 miles beneath the surface. Most diamonds found near the surface were delivered there through deep source volcanic eruptions. pieces of Mantle rock is delivered to the surface without melting, these xenoliths may contain diamonds. The diamond formation is present primarily in the mantle beneath the stable interiors of continental plates. subduction zones can also contain tiny diamonds. Impact sites by asteroids can also lead to tiny diamonds due to the high temperature and pressure surrounding the impact. Some meteorites can also contain nanodiamonds due to high-speed collisions in space. can now be created in labs for commercial use. Other: Industrial diamonds used in cutting, grinding, drilling, and polishing procedures. When diamonds are fashioned into a gem, facet angles are planned to reflect a maximum amount of light from its internal surfaces. High dispersion lets diamonds separate white light into components. 4C's in assessing quality, color, cut, clarity, carat weight. fancy color ones are very rare. Industrial diamonds used for abrasives, small particles are embedded in saw blades, drill bits, and grinding wheels. May also be ground into a fine powder and made into a diamond paste that is used for very fine grinding or polishing. diamonds used to cut and polish other diamonds, none done by lasers. can also be used for diamonds windows, diamond speaker domes, heat sinks, low friction micro bearings, wear-resistant parts. Synthetic diamonds created b high temperature and pressure are HTHP diamonds. The chemical vapor deposition process is CVD diamonds.

Rhodochrosite

Family: Carbonate Formula: Manganese carbonate, but is frequently replaced (Mn,Fe,Mg,Ca)CO3 Color: Pink, red, yellow, gray, brown Habit: Crystal system: Hexagonal Streak: white Luster: vitreous to pearly Crystal Structure: Cleavage: perfect in three directions Fracture: transparent to translucent Tenacity: Hardness: 3.5-4 SG: 3.5-3.7 Diaphaneity: transparent to translucent Formation: usually in fractures and cavities of metamorphic and sedimentary rocks. Assocated with silver deposits. In metamorphic, found as a vein and fracture filling mineral where it precipitates from ascending hydrothermal solutions. Forms in layers.Some form in cavities in sedimentary and metamorphic room when descending solutions deliver a supply of dissolved materials. accumulates in laters and may from stalactites and stalagmites. Other: substitutions change the SG, hardness, and color. weak effervescence with cold dilute HCl, Very popular gemstone. Often slayed to show patterns, slabs used to cut cabochons.

Limonite

Family: Oxide Formula: Fe2O3 Color: Green Habit: Crystal system: Streak: Luster: Crystal Structure: Cleavage: Fracture: Tenacity: Hardness: SG: Diaphaneity: Formation: Other:

Almandine