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Silver chloride

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Chemical compound with the formula AgCl
Silver chloride
Names
IUPAC name Silver(I) chloride
Other names Cerargyrite
Chlorargyrite
Horn silver
Argentous chloride
Identifiers
CAS Number
3D model (JSmol)
ChEBI
ChemSpider
ECHA InfoCard 100.029.121 Edit this at Wikidata
PubChem CID
RTECS number
  • VW3563000
UNII
CompTox Dashboard (EPA)
InChI
  • InChI=1S/Ag.ClH/h;1H/q+1;/p-1Key: HKZLPVFGJNLROG-UHFFFAOYSA-M
  • InChI=1S/Ag.ClH/h;1H/q+1;/p-1
  • Key: HKZLPVFGJNLROG-UHFFFAOYSA-M
SMILES
  • Cl
Properties
Chemical formula AgCl
Molar mass 143.32 g·mol
Appearance White solid
Density 5.56 g cm
Melting point 455 °C (851 °F; 728 K)
Boiling point 1,547 °C (2,817 °F; 1,820 K)
Solubility in water 520 μg/100 g at 50 °C
Solubility product (Ksp) 1.77×10
Solubility soluble in NH3, conc. HCl, conc. H2SO4, alkali cyanide, (NH4)2CO3, KBr, Na2S2O3;

insoluble in alcohol, dilute acids.

Magnetic susceptibility (χ) −49.0·10 cm/mol
Refractive index (nD) 2.071
Structure
Crystal structure cubic
Space group Fm3m (No. 225)
Lattice constant a = 555 pm
Coordination geometry Octahedral
Thermochemistry
Std molar
entropy
(S298)
96 J·mol·K
Std enthalpy of
formation
fH298)
−127 kJ·mol
Hazards
NFPA 704 (fire diamond)
NFPA 704 four-colored diamondHealth 2: Intense or continued but not chronic exposure could cause temporary incapacitation or possible residual injury. E.g. chloroformFlammability 0: Will not burn. E.g. waterInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
2 0 0
Safety data sheet (SDS) Fischer Scientific, Salt Lake Metals
Related compounds
Other anions silver(I) fluoride, silver bromide, silver iodide
Except where otherwise noted, data are given for materials in their standard state (at 25 °C , 100 kPa). ☒verify (what is  ?) Infobox references
Chemical compound

Silver chloride is an inorganic chemical compound with the chemical formula AgCl. This white crystalline solid is well known for its low solubility in water and its sensitivity to light. Upon illumination or heating, silver chloride converts to silver (and chlorine), which is signaled by grey to black or purplish coloration in some samples. AgCl occurs naturally as the mineral chlorargyrite.

It is produced by a metathesis reaction for use in photography and in pH meters as electrodes.

Preparation

Silver chloride is unusual in that, unlike most chloride salts, it has very low solubility. It is easily synthesized by metathesis: combining an aqueous solution of silver nitrate (which is soluble) with a soluble chloride salt, such as sodium chloride (which is used industrially as a method of producing AgCl), or cobalt(II) chloride. The silver chloride that forms will precipitate immediately.

AgNO 3 + NaCl AgCl + NaNO 3 {\displaystyle {\ce {AgNO3 + NaCl -> AgCl(v) + NaNO3}}}
2 AgNO 3 + CoCl 2 2 AgCl + Co ( NO 3 ) 2 {\displaystyle {\ce {2 AgNO3 + CoCl2 -> 2 AgCl(v) + Co(NO3)2}}}

It can also be produced by the reaction of silver metal and aqua regia; however, the insolubility of silver chloride decelerates the reaction. Silver chloride is also a by-product of the Miller process, where silver metal is reacted with chlorine gas at elevated temperatures.

History

Silver chloride has been known since ancient times. Ancient Egyptians produced it as a method of refining silver, which was done by roasting silver ores with salt to produce silver chloride, which was subsequently decomposed to silver and chlorine. However, it was later identified as a distinct compound of silver in 1565 by Georg Fabricius. Silver chloride, historically known as luna cornea (which could be translated as "horn silver" as the moon was an alchemic codename for silver), has also been an intermediate in other historical silver refining processes. One such example is the Augustin process developed in 1843, wherein copper ore containing small amounts of silver is roasted in chloridizing conditions and the silver chloride produced is leached by brine, where it is more soluble.

Silver-based photographic films were first made in 1727 by Johann Heinrich Schulze with silver nitrate. However, he was not successful in making permanent images, as they faded away. Later in 1816, the use of silver chloride was introduced into photography by Nicéphore Niépce.

Structure

Pyramidal crystals of AgCl

The solid adopts the fcc NaCl structure, in which each Ag ion is surrounded by an octahedron of six chloride ligands. AgF and AgBr crystallize similarly. However, the crystallography depends on the condition of crystallization, primarily free silver ion concentration, as is shown in the picture to the left (greyish tint and metallic lustre are due to partially reduced silver).

Above 7.5 GPa, silver chloride transitions into a monoclinic KOH phase. Then at 11 GPa, it undergoes another phase change to an orthorhombic TlI phase.

Reactions

AgCl dissolves in solutions containing ligands such as chloride, cyanide, triphenylphosphine, thiosulfate, thiocyanate and ammonia. Silver chloride reacts with these ligands according to the following illustrative equations:

AgCl ( s ) + 2 CN ( aq ) Ag ( CN ) 2 ( aq ) + Cl ( aq ) {\displaystyle {\ce {AgCl (s) + 2 CN^- (aq) -> Ag(CN)2^- (aq) + Cl^- (aq)}}}
AgCl ( s ) + 2 S 2 O 3 2 ( aq ) ( Ag ( S 2 O 3 ) 2 ) 3 ( aq ) + Cl ( aq ) {\displaystyle {\ce {AgCl (s) + 2 S2O3^2- (aq) ->(Ag(S2O3)2)^3- (aq) + Cl^- (aq)}}}
AgCl ( s ) + 2 NH 3 ( aq ) Ag ( NH 3 ) 2 + ( aq ) + Cl ( aq ) {\displaystyle {\ce {AgCl (s) + 2 NH3(aq) -> Ag(NH3)2+ (aq) + Cl^- (aq)}}}

Of these reactions used to leach silver chloride from silver ores, cyanidation is the most commonly used. Cyanidation produces the soluble dicyanoargentate complex, which is later turned back to silver by reduction.

Silver chloride does not react with nitric acid, but instead reacts with sulfuric acid to produce silver sulfate. Then the sulfate is protonated in the presence of sulfuric acid to bisulfate, which can be reversed by dilution. This reaction is used to separate silver from other platinum group metals.

Most complexes derived from AgCl are two-, three-, and, in rare cases, four-coordinate, adopting linear, trigonal planar, and tetrahedral coordination geometries, respectively.

3 AgCl ( s ) + Na 3 AsO 3 ( aq ) Ag 3 AsO 3 ( s ) + 3 NaCl ( aq ) {\displaystyle {\ce {3AgCl(s) + Na3AsO3(aq) -> Ag3AsO3(s) + 3NaCl(aq)}}}
3 AgCl ( s ) + Na 3 AsO 4 ( aq ) Ag 3 AsO 4 ( s ) + 3 NaCl ( aq ) {\displaystyle {\ce {3AgCl(s) +Na3AsO4(aq) -> Ag3AsO4(s) + 3NaCl(aq)}}}

These two reactions are particularly important in the qualitative analysis of AgCl in labs as AgCl is white, which changes to Ag 3 AsO 3 {\displaystyle {\ce {Ag3AsO3}}} (silver arsenite) which is yellow, or Ag 3 AsO 4 {\displaystyle {\ce {Ag3AsO4}}} (silver arsenate) which is reddish brown.

Chemistry

Silver chloride decomposes over time with exposure to UV light

In one of the most famous reactions in chemistry, the addition of colorless aqueous silver nitrate to an equally colorless solution of sodium chloride produces an opaque white precipitate of AgCl:

Ag + ( aq ) + Cl ( aq ) AgCl ( s ) {\displaystyle {\ce {Ag+ (aq) + Cl^- (aq) -> AgCl (s)}}}

This conversion is a common test for the presence of chloride in solution. Due to its conspicuousness, it is easily used in titration, which gives the typical case of argentometry.

The solubility product, Ksp, for AgCl in water is 1.77×10 at room temperature, which indicates that only 1.9 mg (that is, 1.77 × 10 10   m o l {\displaystyle {\sqrt {1.77\times 10^{-10}}}\ \mathrm {mol} } ) of AgCl will dissolve per liter of water. The chloride content of an aqueous solution can be determined quantitatively by weighing the precipitated AgCl, which conveniently is non-hygroscopic since AgCl is one of the few transition metal chlorides that are insoluble in water. Interfering ions for this test are bromide and iodide, as well as a variety of ligands (see silver halide).

For AgBr and AgI, the Ksp values are 5.2 x 10 and 8.3 x 10, respectively. Silver bromide (slightly yellowish white) and silver iodide (bright yellow) are also significantly more photosensitive than is AgCl.

AgCl quickly darkens on exposure to light by disintegrating into elemental chlorine and metallic silver. This reaction is used in photography and film and is the following:

Cl + → Cl + e (excitation of the chloride ion, which gives up its extra electron into the conduction band)
Ag + e → Ag (liberation of a silver ion, which gains an electron to become a silver atom)

The process is not reversible because the silver atom liberated is typically found at a crystal defect or an impurity site so that the electron's energy is lowered enough that it is "trapped".

Uses

Silver chloride electrode

Silver chloride is a constituent of the silver chloride electrode which is a common reference electrode in electrochemistry. The electrode functions as a reversible redox electrode and the equilibrium is between the solid silver metal and silver chloride in a chloride solution of a given concentration. It is usually the internal reference electrode in pH meters and it is often used as a reference in reduction potential measurements. As an example of the latter, the silver chloride electrode is the most commonly used reference electrode for testing cathodic protection corrosion control systems in seawater environments.

Photography

Silver chloride and silver nitrate have been used in photography since it began, and are well known for their light sensitivity. It was also a vital part of the Daguerreotype sensitization where silver plates were fumed with chlorine to produce a thin layer of silver chloride. Another famous process that used silver chloride was the gelatin silver process where embedded silver chloride crystals in gelatin were used to produce images. However, with advances in color photography, these methods of black-and-white photography have dwindled. Even though color photography uses silver chloride, it only works as a mediator for transforming light into organic image dyes.

Other photographic uses include making photographic paper, since it reacts with photons to form latent images via photoreduction; and in photochromic lenses, taking advantage of its reversible conversion to Ag metal. Unlike photography, where the photoreduction is irreversible, the glass prevents the electron from being 'trapped'. These photochromic lenses are used primarily in sunglasses.

Antimicrobial agent

Silver chloride nanoparticles are widely sold commercially as an antimicrobial agent. The antimicrobial activity of silver chloride depends on the particle size, but are usually below 100 nm. In general, silver chloride is antimicrobial against various bacteria, such as E. coli.

Silver chloride nanoparticles for use as a microbial agent can be produced by a metathesis reaction between aqueous silver and chloride ions or can be biogenically synthesized by fungi and plants.

Other uses

Silver chloride's low solubility makes it a useful addition to pottery glazes for the production of "Inglaze lustre". Silver chloride has been used as an antidote for mercury poisoning, assisting in the elimination of mercury. Other uses of AgCl include:

  • in bandages and wound healing products,
  • to create yellow, amber, and brown shades in stained glass manufacture, and
  • as an infrared transmissive optical component, as it can be hot-pressed into window and lens shapes.

Natural occurrence

Chlorargyrite

Silver chloride occurs naturally as chlorargyrite in the arid and oxidized zones in silver deposits. If some of the chloride ions are replaced by bromide or iodide ions, the words bromian and iodian are added before the name, respectively. This mineral is a source of silver and is leached by cyanidation, where it will produce the soluble complex.

Safety

According to the ECHA, silver chloride may damage the unborn child, is very toxic to aquatic life with long lasting effects and may be corrosive to metals.

See also

References

  1. ^ John Rumble (June 18, 2018). CRC Handbook of Chemistry and Physics (99 ed.). CRC Press. pp. 5–189. ISBN 978-1138561632.
  2. ^ S. Hull; D. A. Keen (1999). "Pressure-induced phase transitions in AgCl, AgBr, and AgI". Physical Review B. 59 (2). APS: 750–761. Bibcode:1999PhRvB..59..750H. doi:10.1103/PhysRevB.59.750. S2CID 123044752.
  3. ^ Zumdahl, Steven S. (2009). Chemical Principles 6th Ed. Houghton Mifflin Company. p. A23. ISBN 978-0-618-94690-7.
  4. ^ Brumby, Andreas (2008). "Silver, Silver Compounds, and Silver Alloys". Ullmann's Encyclopedia of Industrial Chemistry. doi:10.1002/14356007.a24_107.pub2. ISBN 9783527303854.
  5. ^ N. N. Greenwood; A. Earnshaw (1997). Chemistry of the Elements (2 ed.). Oxford, UK: Butterworth-Heinemann. pp. 1173–1200. ISBN 9780750633659.
  6. ^ Potonniée, Georges (1973). The history of the discovery of photography. Arno Press. p. 50. ISBN 0-405-04929-3
  7. ^ Hannavy, John, ed. (2008). Encyclopedia of Nineteenth-Century Photography. Taylor & Francis. p. 857. ISBN 9781135873271.
  8. Susan Watt (2003). Silver. Marshall Cavendish. pp. 21–. ISBN 978-0-7614-1464-3. Retrieved 28 July 2013. ... But the first person to use this property to produce a photographic image was German physicist Johann Heinrich Schulze. In 1727, Schulze made a paste of silver nitrate and chalk, placed the mixture in a glass bottle, and wrapped the bottle in ...
  9. Niépce House Museum: Invention of Photography: 1816-1818, Niépce's first tries (retrieved 2024-02-23)
  10. Wells, A.F. (1984) Structural Inorganic Chemistry, Oxford: Clarendon Press. ISBN 0-19-855370-6. p. 349
  11. Boris A. Sechkarev (1998). "Mass crystallization of silver chloride microcrystals". Microscopy Research and Technique. 42 (2): 145–147. doi:10.1002/(SICI)1097-0029(19980715)42:2<145::AID-JEMT8>3.0.CO;2-S. PMID 9728885. S2CID 45866801.
  12. ^ Etris, Samuel (2003). "Silver Compounds". Kirk-Othmer Encyclopedia of Chemical Technology. doi:10.1002/0471238961.1909122203011616.a01.pub2. ISBN 9780471484943.
  13. ^ Godfrey, S.M.; et al. (1998). "Chapter 3". In Norman, N.C. (ed.). Chemistry of Arsenic, Antimony and Bismuth. Blackie Academic and Professional. ISBN 0-7514-0389-X.
  14. "TEST METHOD FOR TOTAL CHLORINE IN NEW AND USED PETROLEUM PRODUCTS BY OXIDATIVE COMBUSTION AND MICROCOULOMETRY" (PDF). Environmental Protection Agency. September 1994. Archived from the original (PDF) on December 3, 2007.
  15. Bates, R.G. and MacAskill, J.B. (1978). "Standard potential of the silver-silver chloride electrode". Pure & Applied Chemistry, Vol. 50, pp. 1701–1706, http://www.iupac.org/publications/pac/1978/pdf/5011x1701.pdf
  16. "The Daguerreotype Process". Sussex PhotoHistory. Retrieved 19 June 2023.
  17. "SILVER GELATIN" (PDF). Getty.edu. Getty. Retrieved 19 June 2023.
  18. P. Bergthaller (1996). "Silver halide photography". Chemistry and Technology of Printing and Imaging Systems. Springer, Dordrecht. pp. 35–75. doi:10.1007/978-94-011-0601-6_3. ISBN 9789401042659.
  19. R.J. Araujo (2003). "Photochromic Glasses". Encyclopedia of Physical Science and Technology (Third ed.). Academic Press. pp. 49–56. doi:10.1016/B0-12-227410-5/00567-6. ISBN 9780122274107. Retrieved 20 June 2023.
  20. "CVS Health Anti-Microbial Silver Wound Gel". CVS. Retrieved 25 February 2024.
  21. ^ Nelson Durán; Gerson Nakazato; Amedea B. Seabra (2016). "Antimicrobial activity of biogenic silver nanoparticles, and silver chloride nanoparticles: an overview and comments". Applied Microbiology and Biotechnology. 100 (15): 6555–6570. doi:10.1007/s00253-016-7657-7. PMID 27289481. S2CID 253765691.
  22. Yun Ok Kang; Ju-Young Jung; Donghwan Cho; Oh Hyeong Kwon; Ja Young Cheon; Won Ho Park (2016). "Antimicrobial Silver Chloride Nanoparticles Stabilized with Chitosan Oligomer for the Healing of Burns". Materials. 9 (4): 215. Bibcode:2016Mate....9..215K. doi:10.3390/ma9040215. PMC 5502666. PMID 28773340.
  23. John Lowe (1975). "The Conservation of Stained Glass". Studies in Conservation. 2- (1): 93–97. doi:10.1179/sic.1975.s1.016.
  24. "Silver Chloride (AgCl) Optical Material". www.crystran.co.uk. Archived from the original on September 5, 2012. Retrieved 2019-12-04.
  25. "Chlorargyrite". mindat.org. Retrieved 7 June 2023.
  26. "Brief Profile - ECHA". echa.europa.eu. Retrieved 2024-03-27.
Silver compounds
Silver(0,I)
Silver(I)
Organosilver(I) compounds
  • AgC2H3O2
  • AgC22H43O2
  • CH3CH(OH)COOAg
  • C
    18H
    36AgO
    2
  • AgC4H3N2NSO2C6H4NH2
  • AgC
    11H
    23COO
  • Silver(II)
    Silver(III)
    Silver(I,III)
    Salts and covalent derivatives of the chloride ion
    HCl He
    LiCl BeCl2 B4Cl4
    B12Cl12
    BCl3
    B2Cl4
    +BO3
    C2Cl2
    C2Cl4
    C2Cl6
    CCl4
    +C
    +CO3
    NCl3
    ClN3
    +N
    +NO3
    ClxOy
    Cl2O
    Cl2O2
    ClO
    ClO2
    Cl2O4
    Cl2O6
    Cl2O7
    ClO4
    +O
    ClF
    ClF3
    ClF5
    Ne
    NaCl MgCl2 AlCl
    AlCl3
    Si5Cl12
    Si2Cl6
    SiCl4
    P2Cl4
    PCl3
    PCl5
    +P
    S2Cl2
    SCl2
    SCl4
    +SO4
    Cl2 Ar
    KCl CaCl
    CaCl2
    ScCl3 TiCl2
    TiCl3
    TiCl4
    VCl2
    VCl3
    VCl4
    VCl5
    CrCl2
    CrCl3
    CrCl4
    MnCl2
    MnCl3
    FeCl2
    FeCl3
    CoCl2
    CoCl3
    NiCl2 CuCl
    CuCl2
    ZnCl2 GaCl
    GaCl3
    GeCl2
    GeCl4
    AsCl3
    AsCl5
    +As
    Se2Cl2
    SeCl2
    SeCl4
    BrCl Kr
    RbCl SrCl2 YCl3 ZrCl2
    ZrCl3
    ZrCl4
    NbCl3
    NbCl4
    NbCl5
    MoCl2
    MoCl3
    MoCl4
    MoCl5
    MoCl6
    TcCl3
    TcCl4
    RuCl2
    RuCl3
    RuCl4
    RhCl3 PdCl2 AgCl CdCl2 InCl
    InCl2
    InCl3
    SnCl2
    SnCl4
    SbCl3
    SbCl5
    Te3Cl2
    TeCl2
    TeCl4
    ICl
    ICl3
    XeCl
    XeCl2
    XeCl4
    CsCl BaCl2 * LuCl3 HfCl4 TaCl3
    TaCl4
    TaCl5
    WCl2
    WCl3
    WCl4
    WCl5
    WCl6
    ReCl3
    ReCl4
    ReCl5
    ReCl6
    OsCl2
    OsCl3
    OsCl4
    OsCl5
    IrCl2
    IrCl3
    IrCl4
    PtCl2
    PtCl4
    AuCl
    (Au)2
    AuCl3
    Hg2Cl2
    HgCl2
    TlCl
    TlCl3
    PbCl2
    PbCl4
    BiCl3 PoCl2
    PoCl4
    AtCl Rn
    FrCl RaCl2 ** LrCl3 RfCl4 DbCl5 SgO2Cl2 BhO3Cl Hs Mt Ds Rg Cn Nh Fl Mc Lv Ts Og
     
    * LaCl3 CeCl3 PrCl3 NdCl2
    NdCl3
    PmCl3 SmCl2
    SmCl3
    EuCl2
    EuCl3
    GdCl3 TbCl3 DyCl2
    DyCl3
    HoCl3 ErCl3 TmCl2
    TmCl3
    YbCl2
    YbCl3
    ** AcCl3 ThCl3
    ThCl4
    PaCl4
    PaCl5
    UCl3
    UCl4
    UCl5
    UCl6
    NpCl3 PuCl3 AmCl2
    AmCl3
    CmCl3 BkCl3 CfCl3
    CfCl2
    EsCl2
    EsCl3
    FmCl2 MdCl2 NoCl2
    Categories: