Fact-checked by Grok 2 weeks ago

Variscite

Variscite is a relatively rare hydrated aluminum phosphate mineral with the chemical formula AlPO₄·2H₂O, characterized by its vibrant green to blue-green coloration often resembling turquoise, and it typically occurs as cryptocrystalline masses or nodules suitable for use as a semiprecious gemstone.^[1]^[2] This secondary mineral forms through the interaction of phosphatic solutions with aluminum-rich rocks under low-temperature, near-surface conditions, resulting in a waxy to vitreous luster and a Mohs hardness of 3.5 to 4.5, making it relatively soft and prone to scratching.^[1]^[3] The mineral's color variations, ranging from pale mint green to deeper emerald tones or even bluish hues, arise from trace impurities such as chromium, vanadium, and iron, with rarer varieties exhibiting red or violet shades due to ferric iron substitution.^[2]^[4] Variscite has a specific gravity of approximately 2.3 to 2.6, conchoidal fracture, and is generally translucent to opaque, though thin sections can appear nearly colorless under transmitted light.^[1]^[3] It belongs to the orthorhombic crystal system but rarely forms distinct crystals, instead appearing in massive, botryoidal, or stalactitic habits, and it is commonly associated with other phosphate minerals like wavellite, crandallite, and quartz.^[1]^[2] Variscite was first described in 1837 from the Vogtland region in Saxony, Germany—its type locality, historically known as Variscia, from which the mineral derives its name—and it has since been identified in various global deposits, primarily in sedimentary or altered igneous rocks.^[4]^[1] Key occurrences include the Fairfield and Lucin districts in Utah, USA, which supply much of the commercial material; other notable localities are in Nevada and Arkansas (USA), Queensland (Australia), Minas Gerais (Brazil), and the Sureanu Mountains (Romania).^[4]^[3] It forms via supergene processes or low-temperature hydrothermal activity, often in brecciated sandstones, clay sediments influenced by guano deposits, or phosphate-rich weathering zones.^[1]^[5] As a gem material, variscite has been valued since Neolithic times, with artifacts such as beads from over 6,000 years ago found in sites across Europe, including Brittany, France, and sourced from places like Sardinia.^[4] Today, it is primarily cut into cabochons, beads, and slabs for jewelry, ornamental carvings, and collector specimens, prized for patterns like "spiderweb" inclusions of iron oxides or quartz that enhance its aesthetic appeal.^[4]^[3] Its value is determined by color intensity, pattern quality, and size, though it remains more affordable than turquoise due to abundant supply from Utah deposits, and it requires gentle care to avoid damage from acids or heat.^[4]

Chemical and Physical Properties

Composition and Formula

Variscite is a hydrated aluminum phosphate mineral with the chemical formula \ce{AlPO4 \cdot 2H2O}.^[6] This composition classifies it within the phosphate group of minerals, where aluminum serves as the primary cation coordinated with phosphate tetrahedra and water molecules.^[7] The molecular weight of variscite is 157.98 g/mol, calculated from its ideal end-member formula.^[6] Its elemental composition, based on this formula, includes aluminum at 17.08%, phosphorus at 19.61%, oxygen at 60.76%, and hydrogen at 2.55% by weight.^[1] Natural specimens may incorporate trace impurities such as iron, chromium, or vanadium, which substitute for aluminum or enter interstitial sites within the structure.^[8] Variscite is the orthorhombic member of the variscite-metavariscite dimorphous pair, where metavariscite represents the monoclinic polymorph sharing the same chemical formula but differing in atomic arrangement.^[7] It also participates in the variscite-strengite series, involving isomorphous substitution of iron for aluminum in related phosphate structures.^[7] The dihydrate hydration state of variscite imparts structural stability under near-surface conditions, with dehydration occurring primarily as a function of temperature rather than pressure.^[9] Experimental studies indicate stability up to below 113 °C at atmospheric pressure and around 150°C at 4–5 kbar, beyond which it transitions to anhydrous aluminum phosphates like berlinite.^[9] This behavior underscores its formation in low-temperature aqueous environments.^[9]

Crystal Structure

Variscite crystallizes in the orthorhombic crystal system, belonging to the dipyramidal class with point group symmetry 2/m 2/m 2/m.^[7] Its atomic arrangement is defined by the space group Pbca (no. 61), which accommodates the hydrated aluminum phosphate framework through a specific layering of AlO₆ octahedra and PO₄ tetrahedra linked by hydrogen bonds from the water molecules.^[1] This structure results in a relatively open lattice that contributes to the mineral's typical massive or cryptocrystalline habits rather than well-formed crystals. The unit cell of variscite is characterized by approximate parameters a ≈ 9.82 Å, b ≈ 8.56 Å, c ≈ 9.63 Å, with a volume of about 809 Å³ and Z = 8 formula units per cell.^[1] These dimensions reflect the orthorhombic symmetry, where the a and c axes are nearly equal, leading to pseudo-tetragonal appearances in some specimens, though the structure is distinctly orthorhombic.^[7] Variations in cell parameters occur due to minor substitutions, such as partial replacement of Al by Fe, but the core topology remains consistent across samples. Variscite exhibits imperfect cleavage, good on the {010} plane and poor on {001}, which influences its breakage along these directions in crystalline forms.^[1] Its fracture is typically uneven to splintery, though it can appear sub-conchoidal to conchoidal in fine-grained or glassy varieties.^[7] Twinning is rare and occurs on the {201} plane, occasionally producing intergrowths that subtly alter optical properties.^[1] Variscite is dimorphous with metavariscite, the latter adopting a monoclinic structure (space group P2₁/c) with a more distorted lattice due to different hydrogen-bonding arrangements, despite sharing the same chemical composition AlPO₄·2H₂O.^[10] Within the orthorhombic form, two polytypes exist: variscite-1O (Lucin-type) and variscite-2O (Messbach-type), distinguished by their octahedral-tetrahedral layer stacking sequences. The variscite-2O polytype features a doubled b unit-cell parameter compared to variscite-1O, arising from an ordered repetition of layers, and is interpreted as a higher-temperature variant in synthetic studies.^[11]

Appearance and Diagnostic Features

Variscite is typically characterized by its green coloration, ranging from pale to emerald green, with occasional blue-green or yellow varieties; this hue arises from trace amounts of chromium or vanadium impurities.^[1]^[8] The mineral produces a white streak, which aids in its identification.^[1]^[12] In terms of luster, variscite exhibits a waxy to vitreous sheen in crystalline forms, while massive varieties often appear earthy.^[1] It is generally translucent to opaque, with transparency varying based on crystal size and inclusions.^[4] The Mohs hardness ranges from 3.5 to 4.5, making it relatively soft and prone to scratching, while its specific gravity falls between 2.5 and 2.6.^[1]^[12] Optically, variscite displays refractive indices of α = 1.563, β = 1.588, and γ = 1.594, with a birefringence of 0.031; it shows no pleochroism.^[1]^[4] These properties, combined with its diagnostic white streak and green tones, distinguish variscite in gemological assessments.^[13]

Geological Formation and Occurrence

Formation Processes

Variscite primarily forms as a secondary mineral through low-temperature hydrothermal processes, where phosphate-rich fluids interact with and alter aluminum-bearing rocks such as bauxite, clays, or aluminosilicates.^[3] These fluids deposit variscite in veins or nodules within fractured or porous host rocks, often in fault zones where circulation is facilitated.^[14] The process involves the dissolution and reprecipitation of phosphorus and aluminum, leading to the crystallization of variscite under relatively mild geochemical conditions.^[15] Phosphorus for variscite formation typically derives from the weathering or hydrothermal breakdown of primary phosphate minerals like apatite, while aluminum is sourced from the alteration of aluminous rocks or sediments.^[15] This occurs in acidic environments (pH <6), often around 2–5, favorable for phosphate mobilization and precipitation, and at low temperatures typically below 150°C, including near-surface conditions without high-energy metamorphism.^[15]^[16]^[17] Microbial activity in some settings, such as soils or caves, can further enhance formation by producing organic acids that lower pH and mobilize phosphates.^[15] Variscite commonly appears in paragenesis with minerals like quartz, limonite, crandallite, and wavellite, reflecting shared phosphate-rich depositional environments in altered zones.^[3]^[14] Supergene processes also play a key role, with weathering in oxidized zones of sedimentary or igneous terrains promoting enrichment through leaching and secondary precipitation, often concentrating variscite in near-surface deposits.^[3]^[15]

Major Deposits and Localities

Variscite deposits are primarily associated with phosphate-rich hydrothermal alterations in aluminous rocks, occurring as nodules, veins, or crusts in limestone, greisen, or clay environments. The most significant commercial production has historically come from the United States, particularly Utah, where small-scale open-pit mining targeted gem-quality nodules in the early to mid-20th century.^[14] Today, extraction is largely limited to hobbyist and collector activities due to the mineral's niche demand in the lapidary trade.^[18] In the United States, the Clay Canyon deposit near Fairfield, Utah, stands as the largest and most renowned locality, situated in the Sunshine Mining District of the Oquirrh Mountains. Discovered in 1893, it yielded high-quality variscite nodules from brecciated limestone zones, with notable mining efforts in the 1900s and 1930s–1940s, including operations by the Occidental company (producing around 45,000 carats in 1908) and later by Ed Over at the Little Green Monster Mine.^[14]^[19] This site contributed substantially to the U.S. supply for jewelry and specimens until the 1950s, after which reserves dwindled and activity shifted to recreational digging.^[20] Other Utah localities, such as Lucin and Snowville, have produced exceptional green nodules historically, though on a smaller scale.^[14] In Virginia, variscite occurs sporadically in the Farmville Mining District of Buckingham County, notably at the Willis Mountain Mine, where it forms in association with other phosphates but has seen minimal commercial extraction. Europe hosts several classic variscite occurrences, often tied to historical or prehistoric mining. In England, the Tavistock area of Devon has yielded variscite from old quarries and mines, such as High Down Quarry, where it appears as green crusts in phosphate-rich veins, though production was always small-scale and predates modern records.^[21] The Krásno ore district in the Czech Republic, part of the Karlovy Vary Region, features notable deposits at Vysoký Kámen, where variscite forms crystalline aggregates in greisen associated with tin-tungsten mineralization; these sites have been studied for their rare phosphate assemblages but not extensively mined for variscite alone.^[22] Germany's Vogtland region, the mineral's type locality (originally termed "Variscia"), produced early specimens from small veins in schists, contributing to its initial description in 1837, while Spain's Encinasola district in Huelva Province includes the prehistoric Pico Centeno site, where open-trench mining for variscite nodules dates to around 5200 BC and peaked in the 3rd millennium BC, supporting widespread Neolithic trade networks.^[23] Additional notable deposits exist outside North America and Europe. In Australia, Queensland hosts variscite in nodule form within weathered phosphate zones, with small-scale collection for gem purposes ongoing.^[24] Brazil's Minas Gerais state yields scattered occurrences in pegmatites and altered rocks, primarily for local lapidary use, while other sites in the country remain underexplored.^[25] Overall, global variscite mining remains non-commercial, focused on high-quality nodules for ornamental applications rather than bulk production.^[1]

History and Etymology

Discovery and Naming

Variscite was first described as a distinct mineral species in 1837 by the German mineralogist Johann Friedrich August Breithaupt, who examined specimens collected from the Meßbach Quarry in the Vogtland region of Saxony, Germany.^[1] These specimens occurred as crusts on aluminous rocks, marking the type locality for the mineral.^[16] Breithaupt's description appeared in the Journal für praktische Chemie, establishing variscite through detailed observation and initial chemical examination.^[1] Prior to this formal recognition, Breithaupt had described a similar material as "peganite" in 1830 from a locality near St. Riegi, close to Freiberg in Saxony, but the 1837 analysis redefined and renamed it variscite to reflect its unique characteristics.^[14] This classification differentiated variscite as a hydrated aluminum phosphate mineral, distinct from turquoise-like stones that had previously led to misidentifications.^[16] The name "variscite" originates from "Variscia," the ancient Latin designation for the medieval Vogtland region, chosen by Breithaupt to honor the site of its initial discovery.^[1] Early 19th-century specimens were often mistaken for turquoise due to their similar green hues and phosphate associations, but chemical analyses during this period confirmed variscite's unique composition, resolving the confusion.^[26]

Historical and Cultural Uses

Variscite has been utilized in human artifacts since the Neolithic period in Europe, where it was mined and fashioned into beads, pendants, and amulets for burial purposes. Archaeological evidence from sites in Spain, such as Gavà, dating to approximately 7200–6500 years ago (c. 5200–4500 BCE), reveals variscite ornaments including faceted beads, perforated pendants, and complete necklaces interred with high-status individuals, often alongside other grave goods like vessels and flint tools.^[27] These items were produced through collective mining efforts involving both genders, with the stone traded extensively up to 375 km northward into France and Italy, indicating early networks of gemstone exchange and variscite's role in signifying social prestige. Similarly, Neolithic burials in France, such as at Carnac and Pompignan, have yielded variscite bead necklaces and deposits, underscoring its funerary and symbolic importance in prehistoric Atlantic facade cultures.^[28] Variscite sourced from Sardinian deposits, such as the Arbus mines, also contributed to these trade networks, appearing in Neolithic artifacts across the Mediterranean.^[4] In the ancient Near East, variscite served as a gemstone in jewelry and personal ornaments, often valued for its green luster resembling turquoise. Scientific analysis of artifacts from the Late Bronze Age royal tomb at Qatna in Syria (circa 14th century BCE) confirms variscite's use as raw material for adornments, marking the first documented evidence of its application in Middle Eastern contexts.^[29] This site, situated within the Mesopotamian cultural sphere, highlights variscite's prestige in elite burials, where its visual similarity to turquoise likely contributed to its selection for high-status items. While direct evidence from Egyptian sites remains limited, the stone's green hue in broader ancient traditions evoked themes of growth and vitality, aligning with symbolic associations of green minerals for renewal and life force.^[29]^[30] Variscite's prominence waned in later historical periods but experienced a revival in the 19th and 20th centuries, particularly in artistic and lapidary contexts. During the Art Nouveau era (late 19th to early 20th century), it appeared in European jewelry designs, such as cabochon-set pendants and rings featuring organic motifs, capitalizing on the movement's emphasis on natural forms and colored stones.^[31] In the United States, mining in Utah's Clay Canyon near Fairfield, active since the early 1900s and intensifying in the 1930s, supplied material for Southwestern Native American crafts, where artisans like the Navajo incorporated variscite into silver jewelry as a turquoise alternative, reviving traditional inlay and beadwork techniques.^[32]^[33] This period also saw variscite's resurgence in the growing lapidary hobby, promoted through publications like Desert Magazine in the 1940s, which encouraged enthusiasts to cut and polish the stone for ornamental use.^[34] In cultural traditions, variscite lacks prominent mythological roles but holds significance in modern spiritual practices, particularly for its association with emotional healing and the heart chakra in New Age contexts, where its green color is linked to compassion and balance. Native American communities in the Southwest have integrated it into contemporary crafts, viewing it as a stone of harmony, though prehistoric use in the region remains undocumented compared to turquoise.^[35] Overall, variscite's historical trajectory reflects a shift from elite prehistoric and ancient adornments to accessible 20th-century artisanal revival, without the synthetic dyes impacting its niche appeal in natural gemworking.

Applications and Uses

Jewelry and Lapidary Arts

Variscite is most commonly prepared for jewelry through cabochon cutting, as its nodular formations lend themselves well to this technique, producing smooth, polished stones that highlight the mineral's attractive green hues and patterns. Lapidaries typically work with nodules ranging up to 10 cm in diameter, slicing and shaping them into ovals, rounds, or freeforms to maximize color uniformity and veining. Faceting is rare due to the material's softness and lack of transparency in most specimens, though some chatoyant varieties may occasionally be cut this way to accentuate silky inclusions. Doublets, where variscite is backed with stabilizing materials like glass or basalt, are also employed to enhance durability for wearable pieces.^[4]^[13]^[36] In design applications, variscite excels in beads, pendants, and inlays, often set in sterling silver to complement its earthy tones in bohemian or Native American-inspired styles. Beaded necklaces feature graduated strands showcasing the stone's translucency, while pendants and earrings highlight carved motifs like leaves or abstract patterns. Inlays adorn silver cuffs or rings, creating mosaic effects with matrix inclusions for a rustic aesthetic. These uses capitalize on variscite's affordability and availability in larger sizes, making it suitable for statement jewelry.^[36]^[13]^[4] Among varieties prized for jewelry, "Utah teal" or Utahlite from the Little Green Monster Mine stands out for its high-quality light to emerald-green color with white veining, ideal for cabochons up to 20 carats or more. However, variscite's porosity can lead to stability issues, such as absorption of oils or dyes, necessitating sealing with colorless stabilizers before setting. Spiderweb patterns, with dark matrix inclusions, add visual appeal but require careful cutting to preserve integrity.^[36]^[4] Market value for gem-quality variscite typically ranges from $5 to $50 per carat, depending on color saturation, pattern uniformity, and size, with emerald-green specimens commanding higher prices up to $60 per carat. Finished jewelry pieces, such as pendants or rings, retail from $20 to $200, though designer items in silver settings can exceed $700. Factors like rarity of uniform nodules influence pricing, keeping variscite accessible compared to similar gems like turquoise.^[36]^[13] Due to its Mohs hardness of 3.5–4.5, variscite's softness limits it to low-wear applications like pendants or earrings, requiring protective bezel settings to prevent scratches or chipping. Owners should avoid exposure to chemicals, heat, or ultrasonics, as the mineral's hydration can cause cracking or color fading. Routine care involves gentle cleaning with a soft brush, mild detergent, and warm water, followed by thorough drying to mitigate porosity-related damage.^[4]^[36]^[13]

Industrial and Other Applications

Variscite has limited industrial applications due to its relative rarity and low phosphate content, but it plays a notable role in scientific research and geochemical exploration. In mineralogy, variscite is examined for its crystallization processes in phosphate systems, particularly under low-temperature conditions where it forms as a stable phase from aluminum and phosphate interactions.^[37] Its solubility characteristics, influenced by crystal imperfections in natural samples, make it a useful model for understanding phosphate behavior in sedimentary environments and soils.^[38] Researchers also study its dissolution rates compared to amorphous aluminum phosphates, highlighting slower kinetics that inform models of phosphorus release in acidic soils.^[39] As a potential source of aluminum or phosphorus, variscite is uneconomical for extraction, given its trace-level concentrations and the abundance of more viable minerals like bauxite for aluminum or apatite for phosphorus.^[40] No large-scale mining occurs for these purposes, as deposits are typically small and dispersed. In geochemical prospecting, variscite acts as an indicator mineral for phosphate-rich deposits, forming secondarily in aluminous rocks altered by phosphatic waters, which signals potential economic phosphate resources.^[40] Its presence in sediments, such as cave or soil profiles, helps trace phosphorus dynamics and environmental transformations over time.^[15] Beyond research, variscite holds appeal for mineral collectors due to its vibrant green hues and nodular habits, though it lacks significant international export trade, with most specimens sourced from localized U.S. deposits.^[41]

Identification and Similar Minerals

Testing Methods

Variscite specimens can initially be assessed through visual inspection, noting their characteristic pale to emerald-green color, waxy to vitreous luster, and earthy to fine-grained massive texture, which often appears in nodular or stalactitic forms.^[1] This preliminary evaluation helps distinguish potential samples in the field but requires confirmation through physical tests. A simple hardness test involves attempting to scratch the specimen with a copper coin (Mohs hardness 3), which variscite (Mohs 3.5–4.5) will mark, while it fails to scratch a steel knife blade (Mohs 5.5), indicating its intermediate softness; this destructive test should be performed only on rough or inconspicuous areas.^[4]^[1] The streak test, conducted by rubbing the specimen on an unglazed porcelain plate, produces a white mark, and specific gravity can be approximated in the field via water displacement in a graduated container, yielding a low value of 2.57–2.61 g/cm³ for crystalline forms or 2.2–2.5 g/cm³ for massive varieties.^[1]^[6] For laboratory verification, X-ray diffraction (XRD) analysis confirms variscite's orthorhombic crystal system by matching powder diffraction patterns, such as key d-spacings from Cu Kα radiation available in standard databases.^[1] Under long-wave ultraviolet (UV) light, variscite exhibits weak grass-green fluorescence, aiding in initial screening.^[6] Chemical tests provide definitive phosphate identification: fine-grained variscite is slightly soluble in dilute hydrochloric acid (HCl) without effervescence, and adding ammonium molybdate reagent to the acidified solution produces a yellow phosphomolybdate precipitate, confirming the PO₄ presence.^[1]^[42] Fourier transform infrared (FTIR) spectroscopy further verifies the mineral by detecting characteristic absorption bands for OH stretching around 3000–3500 cm⁻¹ and PO₄ symmetric stretching at 1000–1100 cm⁻¹, with a prominent peak near 1030 cm⁻¹ for the P–O mode.^[43]^[44]

Distinction from Look-Alikes

Variscite is frequently mistaken for other green to blue-green minerals due to overlapping color ranges, but it can be distinguished through differences in hardness, chemical composition, streak, cleavage, luster, and reactivity to acids. Its blue-green hues arise from trace amounts of iron and aluminum in the hydrated phosphate structure, without copper, which imparts color to many mimics.^[1]^[13] Compared to turquoise, variscite is softer, with a Mohs hardness of 3.5–4.5 versus turquoise's 5–6, making it more prone to scratching. Variscite lacks copper, responsible for turquoise's characteristic blue tones, and instead derives its green from aluminum and iron; its streak is white, while turquoise's is pale greenish-blue to white. Both exhibit waxy luster and no prominent cleavage in massive forms, but variscite's lower specific gravity (2.5–2.7) compared to turquoise's (2.6–2.8) aids differentiation.^[13]^[1]^[45]^[46] Unlike amazonite, a variety of microcline feldspar colored blue-green by lead impurities, variscite lacks the perfect cleavage in two directions at nearly 90 degrees typical of feldspars and has a more waxy rather than vitreous luster. Amazonite's hardness reaches 6–6.5, far exceeding variscite's, and its streak is white without the subtle translucency variscite shows in thin sections.^[1]^[47] Variscite differs from chrysocolla, an amorphous copper silicate, by being harder (3.5–4.5 versus 2–4) and less porous, with no cleavage observed in its microcrystalline aggregates compared to chrysocolla's earthy to botryoidal habit lacking cleavage. Chrysocolla's blue-green color stems from copper, and it decomposes in hydrochloric acid, often forming a silica gel, but without effervescence, while variscite shows only slight solubility in acid. Both have white streaks, but variscite's vitreous to waxy luster contrasts with chrysocolla's often dull appearance.^[1]^[48] In contrast to malachite, a copper carbonate with deeper green shades from copper and distinctive banding, variscite lacks such banding and does not effervesce with carbon dioxide in dilute acid, as it is a non-carbonate phosphate. Malachite has perfect cleavage on {201} and a light green streak, while variscite's cleavage is good on {010} but poorer on {001}, with a white streak; their hardness ranges overlap at 3.5–4.5 for malachite and 3.5–4.5 for variscite, but malachite's monoclinic system versus variscite's orthorhombic provides crystallographic distinction.^[1]^[49] Pseudomalachite, a copper phosphate with similar chemistry but lacking variscite's full hydration, shares green hues from copper but crystallizes in the monoclinic system rather than variscite's orthorhombic. Variscite's aluminum-dominant formula (AlPO₄·2H₂O) contrasts with pseudomalachite's copper-rich Cu₅(PO₄)₂(OH)₄, resulting in variscite's white streak and lower specific gravity (around 2.6) versus pseudomalachite's higher value (3.6–4.34); hardness is comparable at 4–4.5 for both, but variscite's waxy luster and lack of copper aid identification.^[1]^[50]

References

[1]
Variscite: Mineral information, data and localities.
Geological Setting: Deposited from phosphatic waters reacting with aluminous rocks at surface or near-surface conditions. Type Occurrence of VarisciteHide.
[2]
Variscite from Central Tajikistan: Preliminary Results - GIA
The general chemical formula of variscite group minerals is A(XO4)·2H2O, where A = Al, Fe3+, In and X = P, As. Phosphate members of the variscite group ( ...Missing: composition | Show results with:composition
[3]
Variscite | Properties, Formation, Occurrence, Uses - Geology Science
Jun 13, 2023 · Variscite is typically formed in aluminum-rich, phosphate-rich environments, often associated with other secondary minerals. It is commonly ...
[4]
Variscite Value, Price, and Jewelry Information - Gem Society
Nov 20, 2023 · Although first believed to be turquoise from China, it became evident this material wasn't turquoise but variscite. However, the name callaïs ...Missing: origin | Show results with:origin
[5]
[PDF] Variscite (AlPO4 2H2O) from Cioclovina Cave (Sureanu Mountains ...
The crystal was analyzed at 5 different points. The results of the chemical analyses are listed in Table 1. The empirical formula for variscite is: Al0.695P0.
[6]
Variscite Mineral Data - Mineralogy Database
General Variscite Information ; Help on Chemical Formula: Chemical Formula: AlPO4•2(H2O) ; Help on Composition: Composition: Molecular Weight = 157.98 gm.Missing: reliable sources
[7]
[PDF] Variscite AlPO4 • 2H2O - RRuff
Polymorphism & Series: Dimorphous with metavariscite, forms a series with strengite. Mineral Group: Variscite group. Occurrence: Typically deposited from ...
[8]
The origin of the green color of variscite - GeoScienceWorld
Mar 2, 2017 · Trivalent iron ions, which give only a weak absorption band in some samples, and V3+ ions do not contribute to the green coloration of the ...
[9]
The system Al2O3-P2O5-H2O at temperatures below 200 °C ...
Mar 9, 2017 · The hydration-dehydration equilibrium is mainly controlled by temperature and only weakly by pressure. At 4 and 5 kbar, variscite/metavariscite ...
[10]
Variscite Group: Mineral information, data and localities.
Orthorhombic arsenates and phosphates. Members of the group are isostructural. Phosphate members are isodimorphous with the members of the monoclinic ...<|control11|><|separator|>
[11]
Crystal structure determination of orthorhombic variscite2O and its ...
Jul 1, 2022 · Among the possible solutions, that with the best goodness of fit corresponded to space group Pbca (no. 61). A subsequent WPPD was performed with ...
[12]
Variscite Gem Guide and Properties Chart - Gemstones.com
Variscite is a phosphate mineral that is translucent to opaque with green to bluish green coloring that is often mottled or veined.
[13]
Variscite - A rare mineral and gem material - Geology.com
Variscite is a rare hydrated aluminum phosphate mineral with a chemical composition of AlPO 4 •2H 2 O. It is usually green in color, ranging from yellowish ...
[14]
[PDF] ABSTRACT Variscite color and is used - Utah Geology
These beds may be the source of the phosphate required for variscite formation. Bedding is thin to massive; the thinner units are mostly sandy and weather ...
[15]
Variscite - an overview | ScienceDirect Topics
In acid soils, P can precipitate with Fe and Al, forming minerals such as vivianite, strengite, variscite; in contrast to Ca-phosphate, the solubility of Fe- ...
[16]
Variscite - Dave Crosby - Mindat
Mar 27, 2013 · As at Clay Canyon, production continued into the 1920's when the market diminished. The deposit was generally idle until 1944 When Dr. A. I. ...
[17]
Fairfield Utah Varisite nodules - Mineralogical Society of America
The nodules were first discovered in 1893, and they were mentioned by Kunz (1895) in the Mineral Resources bulletin as a new type of occurrence for variscite.Missing: mining | Show results with:mining
[18]
Clay Canyon & the Little Green Monster Variscite Mine - Mindat
Feb 13, 2015 · Clay Canyon variscite and associated minerals are so spectacular (see above!) they are highly prized for collections.
[19]
[PDF] Eighth supplementary list of British Isles minerals (English)
[The Devon material was probably that exhibited as variscite at a Mineralogical Society meeting in 1962 (Mineral. Mag., 33, lxiv).] Reichenbachite. Monoclinic.
[20]
[PDF] New data on mineralogy of the Vysoký Kámen deposits near Krásno ...
Detailed mineralogical study focused on two deposits located on slopes of the Vysoký Kámen hill near Krásno in the proximity of the town.
[21]
Distribution and chronological framework for Iberian variscite mining ...
Variscite production at Pico Centeno began around 5200 BC, coinciding with the decline of alpine jade. Production peaked in the 3rd millennium BC, with ...
[22]
https://www.jgeosci.org/content/JCGS2006_1-2__sejkora.pdf
[23]
Variscite gemstone information - Gemdat.org
Specific Gravity, 2.42 to 2.58. Walter Schumann, Gemstones of the world (2001) ... Refractive Index, 1.560 to 1.594. Herve Nicolas Lazzarelli, Blue Chart ...Missing: streak luster
[24]
The system Al2O3-P2O5-H2O at temperatures below 200 °C ...
Mar 9, 2017 · The hydrated Al-phosphate variscite (AlPO4·2H2O, orthorhombic) was discovered by Breithaupt ... Prominent examples of natural variscite ...
[25]
Mineralogical Collections of the TU Bergakademie Freiberg (Mining ...
The 102 type specimens are wellpublished [5]. The stored samples from a large number of student theses, dissertations, research projects and field trips are ...Missing: Variscite | Show results with:Variscite
[26]
https://www.gemselect.com/other-info/gemstone-names.php
[27]
Miners in Iberia 5,300 years ago had high social status and rich burials
Mar 14, 2015 · The miners shaped the mineral variscite into ornamental beads and pendants and traded 375 km (233 miles) north into France and Italy and to the ...
[28]
Variscite necklace beads from the Neolithic site of Saint Michael,...
At the European recent Prehistory variscite was a precious gemmological material that appears in scarce megalithic burials of the Atlantic facade ...Missing: amulets | Show results with:amulets
[29]
Use of variscite as a gemstone in the Late Bronze Age Royal Tomb ...
Aug 6, 2025 · The blue pigments were identified as two different pigments, Egyptian blue and cobalt blue.
[30]
https://fiercelynxdesigns.com/blogs/articles/variscite-stone-properties-uses-and-benefits
[31]
https://www.langantiques.com/art-nouveau-variscite-ring.html
[32]
Variscite from Snowville, Curlew Valley, Box Elder County, Utah, USA
Variscite, with formula AlPO4 · 2H2O, is found in Snowville, Curlew Valley, Box Elder County, Utah, USA.
[33]
Utah Variscite | Rock Tumbling Hobby
it was first claimed by C. J. Burk in 1902. He thought it was copper/gold, and dug a pit about20 feet deep. Finding no gold nor copper, he abandoned it. Frank ...<|separator|>
[34]
[PDF] march 1945 - Desert Magazine
And of course if you are a lapidary or a mineralogist it is. "must" for your library. It is one of my favorite volumes. Thomas Y. Crowell Co., New York,. 1940.
[35]
https://www.gemmesterra.com/variscite-serenity-and-emotional-balance/
[36]
Variscite Gemstone: Properties, Meanings, Value & More
### Variscite Jewelry Uses Summary
[37]
The system Al2O3-P2O5-H2O at temperatures below 200 C
Variscite stability likely lies between 115-150 °C at atmospheric pressure, corroborating previous studies. Hydrothermal experiments conducted at pressures of ...
[38]
Chapter 5: Soil phosphates - CTAHR
In soils the solubility product of variscite is about 10 times higher than this (10-29.5) because the crystals are much smaller (if any) and imperfect. However, ...Missing: research crystallization
[39]
[PDF] Dissolution Rates of Amorphous Al- and Fe-Phosphates and their ...
May 1, 2013 · Amorphous Al- phosphates measured in this study are also faster than the crystalline Al phosphate variscite. Lines represent the rate laws ...Missing: applications crystallization<|separator|>
[40]
[PDF] Phosphate Deposits
Where the terrane consists of igneous rocks, alumi- num or iron phosphates such as variscite or strengite are the secondary minerals (Hutchinson, 1952). In ...
[41]
[PDF] Scandium-Bearing Aluminum Phosphate Deposits of Utah
That study also determined that scandium enrichment accompanied alter- ation of variscite to crandallite and other late-stage minerals.
[42]
(PDF) Variscite dissolution rates in aqueous solution - ResearchGate
Aug 7, 2025 · It consists of an acidified solution of ammonium molybdate containing ascorbic acid and a small amount of antimony. This reagent reacts ...
[43]
Variscite, strengite, scorodite and mansfieldite - ScienceDirect.com
The variscite spectrum showed a shift towards higher wavenumbers in comparison to the strengite spectrum with the strongest band observed at 1030 cm− 1 and ...
[44]
The Gemological and Mineral Characteristics of Variscite from Ma ...
The testing methods of Electron Probe Microanalysis (EPMA), X-ray Powder Diffraction (XRD) analysis, Scanning Electron Microscope (SEM), Fourier Transform ...Missing: identification | Show results with:identification
[45]
Turquoise as a Mineral and Gemstone | Uses and Properties
Turquoise is a bright blue to blue-green mineral that has been used to produce gemstones and small sculptures for over 6000 years.
[46]
Feldspar minerals make up over 50% of Earth's crust. - Geology.com
Right-angle cleavage: One of the most diagnostic properties of feldspar is its two directions of cleavage that usually intersect at or close to ninety degrees.
[47]
Malachite: Uses and properties of the mineral and gemstone
It has perfect cleavage and a Mohs hardness of 3.5 to 4. These limit its use to items that will not suffer abrasion and impact. It is also sensitive to heat and ...Missing: amazonite | Show results with:amazonite
[48]
Pseudomalachite: Mineral information, data and localities.
Hardness: 4 - 4½ ; Specific Gravity: 3.6 - 4.34 ; Crystal System: Monoclinic ; Name: From the Greek ψευδής for "false" for its similarity to, but not being, ...