Hubbry Logo
ChlorargyriteChlorargyriteMain
Open search
Chlorargyrite
Community hub
Chlorargyrite
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Chlorargyrite
Chlorargyrite
Chlorargyrite
View on Wikipedia
from Wikipedia
Chlorargyrite
General
CategoryHalide
FormulaAgCl
IMA symbolCag[1]
Strunz classification3.AA.15
Crystal systemIsometric
Crystal classHexoctahedral (m3m)
H-M symbol (4/m 3 2/m)
Space groupFm3m
Identification
ColorColorless when fresh; alters to bright chartreuse-green, light yellow, light green, grey, violet-brown on exposure to light
Crystal habitMassive to columnar
FractureIrregular/uneven, sub-conchoidal
TenacitySectile
Mohs scale hardness1.5–2.5
LusterAdamantine, resinous, waxy
StreakWhite
Specific gravity5.556
Optical propertiesIsotropic
Refractive indexn = 2.071
References[2][3][4]

Chlorargyrite is the mineral form of silver chloride (AgCl).[5] Chlorargyrite occurs as a secondary mineral phase in the oxidation of silver mineral deposits. It crystallizes in the isometric–hexoctahedral crystal class. Typically massive to columnar in occurrence it also has been found as colorless to variably yellow cubic crystals. The color changes to brown or purple on exposure to light. It is quite soft with a Mohs hardness of 1 to 2 and dense with a specific gravity of 5.55. It is also known as cerargyrite and, when weathered by desert air, as horn silver. Bromian chlorargyrite (or embolite) is also common. Chlorargyrite is water-insoluble.

It occurs associated with native silver, cerussite, iodargyrite, atacamite, malachite, jarosite and various iron–manganese oxides.[3]

It was first described in 1875 for occurrences in the Broken Hill district, New South Wales, Australia. The rich Bridal Chamber deposit at Lake Valley, Sierra County, New Mexico was almost pure chlorargyrite.[6] The name is from the Greek, chloros for "pale green" and Latin for silver, argentum.[4]

See also

[edit]
Wikimedia Commons has media related to Chlorargyrite.

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Chlorargyrite

View on Grokipedia
from Grokipedia
Chlorargyrite is a naturally occurring with the AgCl, representing the mineral form of . It derives its name from the Greek words for and silver, reflecting its composition, and is commonly known as horn silver or cerargyrite due to its waxy, horn-like appearance in massive form. This mineral crystallizes in the isometric system, typically forming as cubic crystals (though rare), crusts, or earthy masses in the oxidized zones of silver deposits, where it arises through enrichment processes in arid environments that prevent rapid decomposition. Chlorargyrite exhibits a resinous to adamantine luster, with colors ranging from colorless or pale yellow when fresh to gray, violet-brown, or upon exposure to ; its streak is , and it is transparent to translucent. Physically, it has a Mohs of 2.5, a specific of 5.556 (measured), an uneven to subconchoidal , and is notably sectile, ductile, and plastic in tenacity, allowing it to be easily deformed. Optically, it is isotropic with a of 2.071. As a minor source of silver, chlorargyrite has historical significance in , particularly in western where it contributed to the formation of notable ore deposits in ghost towns. It is commonly associated with native silver, , cerussite, barite, , and iodargyrite, and may contain substitutions of or iodine, forming dimorphous varieties like bromargyrite. Prominent occurrences are found in arid regions such as the in , in , the Harz Mountains in , and various sites in , , and in the United States.

Name and History

Etymology

The name chlorargyrite derives from the Greek words chloros, meaning "pale green," which refers to one of its common color varieties, and argyros, meaning "silver," alluding to its chemical composition. An older synonym is cerargyrite, formed from the Greek keras (horn) and argyros (silver), reflecting the mineral's typical massive, waxy, and horn-like appearance. This term influenced the common descriptive name horn silver, used particularly for weathered specimens with a resinous luster. The bromian variety, containing significant substitution, is known as embolite, an established name for this intermediate composition within the chlorargyrite group. Similarly, the iodian variety is designated iodargyrite, a that emphasizes the incorporation of iodine alongside silver in its structure.

Discovery and Significance

, a , was first described in 1875 as the species chlorargyrite from the type locality in the Marienberg mining district, Erzgebirge, , ; it had previously been known as cerargyrite since the . This initial identification under the modern name occurred for specimens from oxidized zones of silver-bearing lodes. The description highlighted its cubic and waxy luster, distinguishing it from other silver halides. During the late 19th-century booms, chlorargyrite served as a vital secondary , contributing significantly to production in arid environments where oxidation processes concentrated silver near the surface. At Nevada's , one of the most prolific silver districts in American history, chlorargyrite formed in the shallow oxidized portions of veins, enabling easy extraction and reduction to metallic silver; it was among the key minerals that fueled the district's output, which exceeded 120 million ounces of silver by the 1880s. Similarly, in Australia's deposits, discovered in 1883, chlorargyrite occurred abundantly in the enrichment zones above primary sulfides, supporting the early phases of what became a world-class lead-silver-zinc operation and helping drive Australia's silver exports during the colonial era. By the early , chlorargyrite's economic role diminished sharply due to the rapid exhaustion of accessible oxidized zones in major deposits. In the , these shallow, high-grade chlorargyrite-rich ores were depleted within decades, shifting mining efforts to deeper, more complex ores that required advanced processing techniques. At , the narrow oxidized cap containing chlorargyrite was quickly mined out after initial operations began around , leading to a transition to the underlying massive ores by the and reducing reliance on secondary silver minerals like chlorargyrite. This pattern reflected broader trends in , where surface enrichment waned as deeper primary deposits dominated production.

Properties

Chemical Composition

Chlorargyrite is the naturally occurring mineral form of , characterized by the AgCl. Its elemental composition consists of 75.26% silver (Ag) and 24.74% chlorine (Cl) by weight, yielding a molecular weight of 143.32 g/mol. The mineral exhibits compositional variations through partial substitution of ions by or , forming s. Bromian chlorargyrite, historically known as embolite, has the formula Ag(Cl,Br) where replaces a portion of , typically resulting in a molecular weight around 165.55 g/mol for approximate 1:1 ratios. Similarly, iodian chlorargyrite involves substitution by , approximated as Ag(Cl,I), though pure AgI occurs as the distinct mineral iodargyrite. Chlorargyrite forms a solid solution series with bromargyrite (AgBr), its dimorphous polymorph, allowing for a range of ratios in natural specimens. Chlorargyrite demonstrates chemical stability as it is insoluble in , with a solubility of approximately 0.00019 g/100 mL at 20°C. However, it readily dissolves in aqueous solutions of or due to complex ion formation, such as [Ag(NH₃)₂]⁺ or [Ag(S₂O₃)₂]³⁻, which facilitates its extraction in metallurgical processes.

Crystal Structure

Chlorargyrite crystallizes in the isometric (cubic) system, characterized by high symmetry and equal lattice parameters along all axes. This system reflects the mineral's underlying atomic order, where the arrangement of ions forms a highly symmetric lattice. The of chlorargyrite is Fm3m, a face-centered cubic (No. 225) that allows for the positioning of silver and ions in a repeating throughout the . The unit cell is cubic with a lattice a = 5.549 and contains Z = 4 formula units. In this structure, silver ions (Ag⁺) occupy the corners and face centers of the unit cell at positions equivalent to (0,0,0), while ions (Cl⁻) are located at (0.5,0.5,0.5), forming an interpenetrating lattice. Chlorargyrite adopts the rock salt (NaCl) structure type, a prototypical ionic lattice where each Ag⁺ is octahedrally coordinated by six Cl⁻ , and vice versa, resulting in a of 6 for both cations and anions. This arrangement is stabilized by predominantly between the Ag⁺ and Cl⁻ , with the cubic symmetry arising from the close-packed, alternating layers of the two types that minimize electrostatic repulsion and maximize attraction within the lattice. The rock salt motif underscores chlorargyrite's similarity to other alkali halides.

Physical and Optical Properties

Chlorargyrite is a soft with a Mohs ranging from 1.5 to 2.5, allowing it to be scratched by a fingernail or . It is sectile, ductile, and highly plastic, meaning it can be cut with a and deformed without breaking. The specific gravity of chlorargyrite is 5.55 to 5.56 g/cm³, indicative of its dense composition dominated by silver. Fresh specimens of chlorargyrite are colorless or pale yellow to gray, but the mineral is highly photosensitive and darkens to violet-brown or purplish hues upon exposure to due to photodecomposition. It may also appear or chartreuse in transmitted . The streak is , and the luster ranges from adamantine to resinous or waxy. Chlorargyrite exhibits no cleavage and fractures in a subconchoidal to uneven manner. Optically, chlorargyrite is isotropic with a of n=2.071n = 2.071, resulting in high surface relief under the and no or .

Occurrence and Formation

Geological Formation

Chlorargyrite is a secondary that primarily forms in the oxidation zone of silver deposits, where primary silver minerals undergo and alteration near the Earth's surface. This zone develops above the deeper hypogene ores, as meteoric waters percolate through fractures and interact with exposed or shallow primary minerals, leading to their breakdown and redistribution of silver. The mineral's precipitation occurs as part of the broader enrichment process, which concentrates silver in the upper levels of ore bodies through oxidative leaching and secondary deposition. It can also occur as nodules in saline soils of arid silver-bearing regions or as precipitates from the mixing of silver-bearing waters with chloride-rich solutions. The formation mechanism involves chloridization, a process in which primary silver sulfides, such as argentite (Ag₂S), react with chloride-rich groundwaters to produce chlorargyrite (AgCl). A representative reaction is Ag₂S + 2NaCl + 2O₂ → 2AgCl + Na₂SO₄, where silver is mobilized from sulfides by oxidizing solutions and combines with available chloride ions, often derived from seawater intrusion, dissolution, or saline soil waters. This alteration typically affects native silver and silver sulfosalts as well, transforming them into stable chloride phases under surface conditions. Chlorargyrite formation favors arid to semi-arid climates, where low rainfall preserves the mineral from dissolution and promotes evaporation, concentrating chloride in groundwaters. The process occurs in neutral to mildly acidic solutions with ample oxygen availability, typically in the upper oxidized horizons of bodies where and atmospheric oxygen interact with sulfides. In paragenesis, it commonly co-occurs with species like native silver in these oxidizing environments.

Associated Minerals

Chlorargyrite commonly occurs alongside native silver, (PbCO₃), iodargyrite (AgI), embolite (Ag(Br,Cl)), (Cu₂Cl(OH)₃), (Cu₂CO₃(OH)₂), jarosite (KFe₃(SO₄)₂(OH)₆), and iron-manganese oxides in the environments of silver deposits. These associations reflect the mineral's formation as a secondary phase during the oxidation of primary silver ores, particularly in arid to semi-arid climates where availability is enhanced by and salination. In terms of zonal distribution, chlorargyrite is typically found in near-surface, chloride-rich zones with other silver halides like iodargyrite and embolite, often in close proximity to secondary copper minerals (e.g., , ) and lead carbonates (e.g., ). Iron-manganese oxides and jarosite further indicate acidic, oxidizing conditions that stabilize these parageneses. This mineral assemblage is diagnostic of oxidized, chloride-enriched environments, where high evaporation rates concentrate halides from atmospheric or evaporitic sources, and it rarely coexists with primary sulfides owing to their prior decomposition during oxidation.

Distribution and Localities

Type Locality

The type locality of chlorargyrite is the Marienberg mining district in the Erzgebirgskreis, , . This historic region, part of the (Erzgebirge), features silver ore bodies developed over centuries, with chlorargyrite occurring primarily in the oxidized surface zones of these deposits. Chlorargyrite was first scientifically described in 1875 by August Weisbach in his Synopsis Mineralogica, based on specimens collected from mines in the Marienberg area during systematic mineralogical surveys of Saxon silver workings; these materials define the species as (AgCl). The identification highlighted its cubic and sensitivity to light, distinguishing it from earlier informal references to "horn silver." Today, the Marienberg district is a preserved historical landscape, inactive since 1958 and recognized as part of the World Heritage-listed Erzgebirge/Krušnohoří Mining Region, though recent exploration licenses have been issued for potential new surveys. Type specimens are preserved in institutional collections, including the Ore Deposit Collection at TU Bergakademie .

Major Deposits

Chlorargyrite forms significant deposits in the oxidized zones of silver-bearing systems, particularly in epithermal veins and hydrothermal replacement deposits within arid environments. One of the most renowned historical sites is the Bridal Chamber mine in the Lake Valley district, , USA, where massive, nearly pure chlorargyrite occurred in a bonanza deposit discovered in the late , yielding approximately 2.5 million ounces of silver from this stope alone as part of the district's total output exceeding 5 million ounces between 1878 and the early 1900s. The was so high-grade that it was shipped directly to the U.S. Mint without , with the chamber measuring about 200 feet long and 25 feet thick, representing thousands of tons of extractable silver . In , the Chanarcillo silver district in the of stands out as a major 19th-century producer, where chlorargyrite enriched the zones of silver veins mined extensively from 1830 to 1880, contributing to over 3,000 tons of silver output valued at around $100 million in period dollars. Similarly, the historic Potosí in featured chlorargyrite in the upper oxidized levels of its world-class silver veins, with early production through 1572 including soft chlorargyrite ore assaying up to 25% silver, supporting the extraction of vast quantities that made the largest silver deposit in history. In the United States, the Tombstone in , hosts notable chlorargyrite in the oxidized caps of epithermal silver veins, exemplified by high-grade occurrences in mines like the Santa Ana, which contributed to the area's legendary 19th-century silver boom. Contemporary occurrences of chlorargyrite are more minor but persist in established silver provinces, such as the district in , where it appears in the weathered zones of epithermal veins alongside secondary minerals like . In , the district in remains a key locality for chlorargyrite, often as bromian varieties in the oxidized parts of the massive silver-lead-zinc deposit, with world-class specimens still documented from historic workings. Exploration continues in arid silver-bearing regions globally, targeting similar enrichments for potential new chlorargyrite resources.

Uses and Significance

Economic Importance

Chlorargyrite serves primarily as an ore of silver, containing up to 75.3% silver by weight in its pure form (AgCl), making it one of the richest secondary silver minerals. Historically, its high silver content allowed for direct smelting in bonanza deposits, such as those in the Cerbat Mountains of Arizona during the 1870s–1880s, where oxidized ores rich in chlorargyrite yielded significant production, including up to $1.5 million from individual mines like the Cupel. In other cases, extraction involved leaching with cyanide solutions, where chlorargyrite dissolves rapidly due to its solubility, or ammonia-based processes to form soluble silver complexes, facilitating recovery from chloride-rich zones. Mining of chlorargyrite typically targets shallow oxidized caps in silver deposits, using open-pit methods for surface exposures or underground shafts and tunnels for depths up to 100–300 feet, as seen in historical operations at Chloride Flats, New Mexico, which produced over 3 million ounces in just five years. In modern contexts, recovery may employ to concentrate the ore or hydrometallurgical leaching if the deposit's grade justifies it, though such operations are rare due to the mineral's limited extent. Today, chlorargyrite plays a minor role in global silver production, which overwhelmingly derives from primary sulfide ores like , , and mined as of lead, , and . Its economic viability persists mainly in byproduct recovery from chloride zones in oxidized portions of larger deposits, with no significant byproducts of its own, though it often occurs alongside lead and minerals.

Collectibility

Chlorargyrite appeals to mineral collectors primarily for its distinctive waxy, sectile masses and the scarcity of its well-formed cubic crystals, which can reach sizes up to several millimeters in exceptional cases. Known as "horn silver" in its massive variety, the mineral's color range—from colorless and pale yellow to prized greenish-gray and chartreuse-green tones—adds to its aesthetic value, especially in specimens preserving their fresh appearance. The mineral's collectibility is tempered by inherent challenges, including its low Mohs hardness of 2.5, which renders it soft and prone to scratching or deformation, thereby restricting its suitability for jewelry or decorative wear. Furthermore, chlorargyrite exhibits high , decomposing under light exposure to form metallic silver and gas, resulting in a darkening to violet-brown or purplish hues that diminishes its visual appeal over time. In the collector's market, high-quality specimens from historic localities command premium prices due to their rarity and association with 19th-century mining booms, with fine bromian chlorargyrite examples from the Lake Valley district in —once a major silver producer—being particularly prized. Synthetic (AgCl), while chemically identical, holds no collectible value as it lacks the natural , impurities, and geological provenance that define authentic mineral specimens. Preservation requires careful handling, with specimens ideally stored in dark, dry environments to mitigate light-induced degradation and maintain their original colors. Historical chlorargyrite pieces from sites like Lake Valley not only showcase the mineral's form but also document key episodes in , making them valuable for collections and educational displays.

References

  1. https://www.handbookofmineralogy.org/pdfs/chlorargyrite.pdf
  2. https://galleries.com/minerals/halides/chlorarg/chlorarg.htm
  3. https://www.mindat.org/min-1014.html
  4. http://webmineral.com/data/Chlorargyrite.shtml
  5. https://www.mindat.org/min-11088.html
  6. https://www.mindat.org/min-2037.html
  7. http://www.miningartifacts.org/Nevada-Mines.html
  8. https://westernmininghistory.com/mine-detail/10310576/
  9. https://www.ga.gov.au/education/minerals-energy/australian-mineral-facts/silver
  10. https://nswstatearchives.blog/2015/07/21/broken-hill-100-years-of-mining/
  11. https://pubchem.ncbi.nlm.nih.gov/compound/Silver-Chloride
  12. http://webmineral.com/data/Embolite.shtml
  13. https://www.sciencedirect.com/science/article/abs/pii/S0016703716300114
  14. https://rruff.geo.arizona.edu/AMS/minerals/Chlorargyrite
  15. https://www.researchgate.net/publication/339732680_Spectroscopies_and_Electron_Microscopies_Unravel_the_Origin_of_the_First_Colour_Photographs
  16. https://emrlibrary.gov.yk.ca/gsc/bulletins/160/bulletin160.pdf
  17. https://rruff.info/uploads/CM35_23.pdf
  18. https://rruff.info/chlorargyrite
  19. https://www.mindat.org/loc-1888.html
  20. https://tu-freiberg.de/en/geosam/ore-deposit-collection
  21. https://www.minerals.net/mineral/chlorargyrite.aspx
  22. https://www.blm.gov/blog/2025-02-06/former-boomtowns-second-life-storyteller-new-mexico
  23. https://www.nmmarketplace.com/articles/travel/lake-valley-and-the-bridal-chamber-mine/article_7806c7fa-20cc-11ee-88a8-23d38a9a6612.html
  24. https://www.foro-minerales.com/forum/gen_imag/The_Fettelite_from_Chanarcillo-Copiapo_Chile/The_Fettelite_from_Chanarcillo-Copiapo_Chile.pdf
  25. https://go.gale.com/ps/i.do?id=GALE%257CA54064349&sid=googleScholar&v=2.1&it=r&linkaccess=abs&issn=00264628&p=AONE&sw=w
  26. https://geoinfo.nmt.edu/museum/nmms/abstracts/view.cfm?aid=192
  27. https://www.sciencedirect.com/science/article/abs/pii/S0169136817308491
  28. https://www.mindat.org/locentry-763022.html
  29. https://www.dakotamatrix.com/mineralpedia/5721/chlorargyrite
  30. https://link.springer.com/chapter/10.1007/978-3-031-12654-3_29
  31. https://pubs.usgs.gov/bul/0750b/report.pdf
  32. https://www.sciencedirect.com/science/article/abs/pii/S0167452805150340
  33. https://www.sciencedirect.com/science/article/pii/0304386X9400083F
  34. https://www.thenaturalsapphirecompany.com/education/precious-metal-mining-refining-techniques/silver-mining-refining/
  35. https://pubs.usgs.gov/publication/70135275
  36. https://geoinfo.nmt.edu/tour/landmarks/lake_valley/home.html
  37. https://crystals2collect.com/products/chlorargyrite-embolite-chlorargyrite_bromium-crystals-minerals-rocks-crystals2collect
Add your contribution
Related Hubs
User Avatar
No comments yet.