Log InRegister
Quick Links : The Mindat ManualThe Rock H. Currier Digital LibraryMindat Newsletter [Free Download]
Home PageAbout MindatThe Mindat ManualHistory of MindatCopyright StatusWho We AreContact UsAdvertise on Mindat
Donate to MindatCorporate SponsorshipSponsor a PageSponsored PagesMindat AdvertisersAdvertise on Mindat
Learning CenterWhat is a mineral?The most common minerals on earthInformation for EducatorsMindat ArticlesThe ElementsThe Rock H. Currier Digital LibraryGeologic Time
Minerals by PropertiesMinerals by ChemistryAdvanced Locality SearchRandom MineralRandom LocalitySearch by minIDLocalities Near MeSearch ArticlesSearch GlossaryMore Search Options
Search For:
Mineral Name:
Locality Name:
Keyword(s):
 
The Mindat ManualAdd a New PhotoRate PhotosLocality Edit ReportCoordinate Completion ReportAdd Glossary Item
Mining CompaniesStatisticsUsersMineral MuseumsClubs & OrganizationsMineral Shows & EventsThe Mindat DirectoryDevice SettingsThe Mineral Quiz
Photo SearchPhoto GalleriesSearch by ColorNew Photos TodayNew Photos YesterdayMembers' Photo GalleriesPast Photo of the Day GalleryPhotography

Orthoclase

A valid IMA mineral species - grandfathered
This page kindly sponsored by Robert M. Hazen
07064180017056275366676.jpg
Orthoclase

Pópulo e Ribalonga, Alijó, Vila Real, Portugal
03219560014977259099112.jpg
Orthoclase

Formazza Valley, Verbano-Cusio-Ossola Province, Piedmont, Italy
02570520014952239656294.jpg
Orthoclase

Pitkin County, Colorado, USA
08666930017056051578654.jpg
Orthoclase

Pópulo e Ribalonga, Alijó, Vila Real, Portugal
03219560014977259099112.jpg
Orthoclase

Formazza Valley, Verbano-Cusio-Ossola Province, Piedmont, Italy
00970760014978129296956.jpg
Orthoclase

Pitkin County, Colorado, USA
08666930017056051578654.jpg
Orthoclase

Pópulo e Ribalonga, Alijó, Vila Real, Portugal
03219560014977259099112.jpg
Orthoclase

Formazza Valley, Verbano-Cusio-Ossola Province, Piedmont, Italy
Hide all sections | Show all sections

About OrthoclaseHide

Formula:
K(AlSi3O8)
Colour:
Colorless to white, Greenish white, Grayish yellow, Pale pink
Lustre:
Vitreous, Sub-Vitreous, Resinous
Hardness:
6
Specific Gravity:
2.55 - 2.63
Crystal System:
Monoclinic
Name:
Named "orthose" in 1801 by Rene Just Haüy from the Greek orthos - "right" in allusion to the mineral's right angle of good cleavage. The sense of Haüy's name was that the mineral was a feldspar, but he did not specify a type-locality, nor did Haüy give a chemical analysis. The name was changed in 1823 to orthoklas by Johann Friedrich August Breithaupt.
Feldspar Group. K Feldspar subgroup. Celsian-Orthoclase Series.

An intermediate, partially ordered member of the K-feldspar structural series, between disordered, monoclinic sanidine and completely ordered microcline. Because of its intermediate nature, it’s species status could be questioned, but it has grandfather status.

Although petrologists have long used microscopic twinning and other optical properties as a method of distinguishing orthoclase from microcline and sanidine, Wright and Stewart (1958) used the position of certain d values in XRD patterns to calculate the degree of disorder of a K-feldspar (plus it’s Na content) and thus have a more quantitative method to identify its structural state.

Sanidine forms in rapidly cooled volcanic rocks (eg. Rhyolite) and some high level intrusive dykes, whilst microcline forms in more slowly cooled rocks like granite pegmatites. Orthoclase is the most common member of the series, being the dominant K-feldspar in most granite, granitic rocks and other plutonic rocks, with an intermediate cooling regime. Despite the enormous number of reports of orthoclase in granite pegmatites, orthoclase is rare in pegmatitic pockets. It has, however, been known to be stabilised by structural defects in some pegmatites (eg. Liu et al., 2018). Partially ordered, monoclinic orthoclase may persist metastably at lower temperatures (Prince et al., 1973). It constitutes some hydrothermal “adularia” (some is microcline).

Visit gemdat.org for gemological information about Orthoclase.



Unique IdentifiersHide

Mindat ID:
3026
Long-form identifier:
mindat:1:1:3026:3
GUID
(UUID V4):
0a30602c-12ea-4ee3-bd1f-7a4f9c65f773

IMA Classification of OrthoclaseHide

IMA status:
Approved, 'Grandfathered' (first described prior to 1959)

Classification of OrthoclaseHide

Strunz-mindat (2024):
9.FA.30

9 : SILICATES (Germanates)
F : Tektosilicates without zeolitic H2O
A : Tektosilicates without additional non-tetrahedral anions
Dana 7th ed.:
76.1.1.1
Dana 8th ed.:
76.1.1.1

76 : TECTOSILICATES Al-Si Framework
1 : Al-Si Framework with Al-Si frameworks
Hey's CIM Ref.:
16.3.6

16 : Silicates Containing Aluminum and other Metals
3 : Aluminosilicates of K

Mineral SymbolsHide

As of 2021 there are now IMA–CNMNC approved mineral symbols (abbreviations) for each mineral species, useful for tables and diagrams.

Please only use the official IMA–CNMNC symbol. Older variants are listed for historical use only.

SymbolSourceReference
OrIMA–CNMNCWarr, L.N. (2021). IMA–CNMNC approved mineral symbols. Mineralogical Magazine, 85(3), 291-320. doi:10.1180/mgm.2021.43
OrKretz (1983)Kretz, R. (1983) Symbols of rock-forming minerals. American Mineralogist, 68, 277–279.
OrSiivolam & Schmid (2007)Siivolam, J. and Schmid, R. (2007) Recommendations by the IUGS Subcommission on the Systematics of Metamorphic Rocks: List of mineral abbreviations. Web-version 01.02.07. IUGS Commission on the Systematics in Petrology. download
OrWhitney & Evans (2010)Whitney, D.L. and Evans, B.W. (2010) Abbreviations for names of rock-forming minerals. American Mineralogist, 95, 185–187 doi:10.2138/am.2010.3371
OrThe Canadian Mineralogist (2019)The Canadian Mineralogist (2019) The Canadian Mineralogist list of symbols for rock- and ore-forming minerals (December 30, 2019). download
OrWarr (2020)Warr, L.N. (2020) Recommended abbreviations for the names of clay minerals and associated phases. Clay Minerals, 55, 261–264 doi:10.1180/clm.2020.30

Pronunciation of OrthoclaseHide

Pronunciation:
PlayRecorded byCountry
Jolyon RalphUnited Kingdom

Physical Properties of OrthoclaseHide

Lustre:
Vitreous, Sub-Vitreous, Resinous
Transparency:
Transparent, Translucent
Comment:
Slightly pearly on cleavage
Colour:
Colorless to white, Greenish white, Grayish yellow, Pale pink
Streak:
White
Hardness:
6 on Mohs scale
Hardness Data:
Mohs hardness reference species
Tenacity:
Brittle
Cleavage:
Perfect
Perfect on {001}, good on {010}
Parting:
On {100} {110} {110} {201}
Fracture:
Irregular/Uneven, Conchoidal
Density:
2.55 - 2.63 g/cm3 (Measured)    2.563 g/cm3 (Calculated)

Optical Data of OrthoclaseHide

Type:
Biaxial (-)
RI values:
nα = 1.518 - 1.520 nβ = 1.522 - 1.524 nγ = 1.522 - 1.525
2V:
Measured: 35° to 75°, Calculated: 52° to 70°
Birefringence:
0.004
Max Birefringence:
δ = 0.004 - 0.005
Image shows birefringence interference colour range (at 30µm thickness)
and does not take into account mineral colouration.
Surface Relief:
Low
Dispersion:
r > v distinct
Optical Extinction:
X^a = 6°-14°, Y^c = -13° to 21°, Z = b
Pleochroism:
Non-pleochroic

Chemistry of OrthoclaseHide

Mindat Formula:
K(AlSi3O8)
Elements listed:
Al, K, O, Si - search for minerals with similar chemistry
Common Impurities:
Na,Fe,Ba,Rb,Ca

Crystallography of OrthoclaseHide

Crystal System:
Monoclinic
Class (H-M):
2/m - Prismatic
Space Group:
B2/m
Setting:
C2/m
Cell Parameters:
a = 8.5632(11) Å, b = 12.963(14) Å, c = 7.299(11) Å
β = 116.073(9)°
Ratio:
a:b:c = 0.661 : 1 : 0.563
Unit Cell V:
724.57 ų
Z:
4
Morphology:
Short prismatic
Twinning:
Common as Carlsbad, Baveno and Manebach.

Crystallographic forms of OrthoclaseHide

Crystal Atlas:
Image Loading
Click on an icon to view
Orthoclase no.49 - Goldschmidt (1913-1926)
Orthoclase no.50 - Goldschmidt (1913-1926)
Orthoclase no.58 - Goldschmidt (1913-1926)
Orthoclase no.64 - Goldschmidt (1913-1926)
Orthoclase no.65 - Goldschmidt (1913-1926)
Orthoclase no.76 - Goldschmidt (1913-1926)
Orthoclase no.145 - Goldschmidt (1913-1926)
Orthoclase no.174 - Goldschmidt (1913-1926)
Orthoclase no.410 - Goldschmidt (1913-1926)
Orthoclase no.434 - Goldschmidt (1913-1926)
Orthoclase no.460 - Goldschmidt (1913-1926)
3d models and HTML5 code kindly provided by www.smorf.nl.

Toggle
Edge Lines | Miller Indices | Axes

Transparency
Opaque | Translucent | Transparent

View
Along a-axis | Along b-axis | Along c-axis | Start rotation | Stop rotation

Crystal StructureHide

Load
Unit Cell | Unit Cell Packed
2x2x2 | 3x3x3 | 4x4x4
Show
Big Balls | Small Balls | Just Balls | Spacefill
Polyhedra Off | Si Polyhedra | All Polyhedra
Remove metal-metal sticks
Display Options
Black Background | White Background
Perspective On | Perspective Off
2D | Stereo | Red-Blue | Red-Cyan
View
CIF File    Best | x | y | z | a | b | c
Rotation
Stop | Start
Labels
Console Off | On | Grey | Yellow
IDSpeciesReferenceLinkYearLocalityPressure (GPa)Temp (K)
0019651OrthoclaseViswanathan K, Kielhorn H M (1983) Al,Si distribution in a ternary (Ba,K,Na)-feldspar as determined by crystal structure refinement American Mineralogist 68 122-1241983Yugoslavia0293
0000166OrthoclaseColville A A, Ribbe P H (1968) The crystal structure of an adularia and a refinement of the structure of orthoclase American Mineralogist 53 25-371968St. Gotthard, Switzerland, known as Spencer B, variety adularia0293
0000167OrthoclaseColville A A, Ribbe P H (1968) The crystal structure of an adularia and a refinement of the structure of orthoclase American Mineralogist 53 25-371968St. Gotthard, Switzerland, known as Spencer C0293
0000313OrthoclasePhillips M W, Ribbe P H (1973) The structures of monoclinic potassium-rich feldspars American Mineralogist 58 263-2701973St. Gotthard, Switzerland0293
0000320OrthoclasePrince E, Donnay G, Martin R F (1973) Neutron diffraction refinement of an ordered orthoclase structure American Mineralogist 58 500-5071973Himalaya mine, California, USA0293
0020509OrthoclaseAngel R J, Ross N L, Zhao J, Sochalski-Kolbus L, Kruger H, Schmidt B C (2013) Structural controls on the anisotropy of tetrahedral frameworks: the example of monoclinic feldspars European Journal of Mineralogy 25 597-6142013Unknown0293
0020540OrthoclaseAngel R J, Ross N L, Zhao J, Sochalski-Kolbus L, Kruger H, Schmidt B C (2013) Structural controls on the anisotropy of tetrahedral frameworks: the example of monoclinic feldspars European Journal of Mineralogy 25 597-6142013Unknown0293
0020541OrthoclaseAngel R J, Ross N L, Zhao J, Sochalski-Kolbus L, Kruger H, Schmidt B C (2013) Structural controls on the anisotropy of tetrahedral frameworks: the example of monoclinic feldspars European Journal of Mineralogy 25 597-6142013Unknown0293
0020542OrthoclaseAngel R J, Ross N L, Zhao J, Sochalski-Kolbus L, Kruger H, Schmidt B C (2013) Structural controls on the anisotropy of tetrahedral frameworks: the example of monoclinic feldspars European Journal of Mineralogy 25 597-6142013Unknown0293
0020543OrthoclaseAngel R J, Ross N L, Zhao J, Sochalski-Kolbus L, Kruger H, Schmidt B C (2013) Structural controls on the anisotropy of tetrahedral frameworks: the example of monoclinic feldspars European Journal of Mineralogy 25 597-6142013Unknown0600
0020544OrthoclaseAngel R J, Ross N L, Zhao J, Sochalski-Kolbus L, Kruger H, Schmidt B C (2013) Structural controls on the anisotropy of tetrahedral frameworks: the example of monoclinic feldspars European Journal of Mineralogy 25 597-6142013Unknown0900
0020545OrthoclaseAngel R J, Ross N L, Zhao J, Sochalski-Kolbus L, Kruger H, Schmidt B C (2013) Structural controls on the anisotropy of tetrahedral frameworks: the example of monoclinic feldspars European Journal of Mineralogy 25 597-6142013Unknown01075
0007928OrthoclaseTseng H-Y, Heaney P J, Onstott T C (1995) Characterization of lattice strain induced by neutron irradiation Physics and Chemistry of Minerals 22 399-40519950293
0007929OrthoclaseTseng H-Y, Heaney P J, Onstott T C (1995) Characterization of lattice strain induced by neutron irradiation Physics and Chemistry of Minerals 22 399-40519950293
0007930OrthoclaseTseng H-Y, Heaney P J, Onstott T C (1995) Characterization of lattice strain induced by neutron irradiation Physics and Chemistry of Minerals 22 399-40519950293
0020547OrthoclaseJones J B, Taylor W H (1961) The structure of orthoclase Acta Crystallographica 14 443-4561961Mogok, Upper Burma0293
0020550OrthoclaseDal Negro A, De Pieri R, Quareni S (1978) The crystal structures of nine K feldspars from the Adamello Massif (Northern Italy) Acta Crystallographica B34 2699-27071978Adamello Massif, Northern Italy0293
0020551OrthoclaseDal Negro A, De Pieri R, Quareni S (1978) The crystal structures of nine K feldspars from the Adamello Massif (Northern Italy) Acta Crystallographica B34 2699-27071978Adamello Massif, Northern Italy0293
0020552OrthoclaseDal Negro A, De Pieri R, Quareni S (1978) The crystal structures of nine K feldspars from the Adamello Massif (Northern Italy) Acta Crystallographica B34 2699-27071978Adamello Massif, Northern Italy0293
0020553OrthoclaseFenn P M, Brown G E (1977) Crystal structure of a synthetic, compositionally intermediate, hypersolvus alkali feldspar: evidence for Na, K site ordering Zeitschrift fur Kristallographie 145 124-1451977Synthetic0293
0020546OrthoclaseGering E (1985) Silizium/Aluminium-Ordnung und Kristallperfektion von Sanidinen Dissertation Kernforshungszentrum Karlsruhe 1 1-971985Madagascar0293
0018075OrthoclaseChao S, Hargreaves A, Taylor W (1940) The structure of orthoclase. _cod_database_code 1011205 Mineralogical Magazine 25 498-51219400293
0020548OrthoclaseKimata M, Saito S, Shimizu M, Iida I, Matsui T (1996) Low-temperature structures of orthoclase and sanidine Neues Jahrbuch fur Mineralogie, Abhandlungen 171 199-2131996Itrongay, Madagascar0121
0020549OrthoclaseKimata M, Saito S, Shimizu M, Iida I, Matsui T (1996) Low-temperature structures of orthoclase and sanidine Neues Jahrbuch fur Mineralogie, Abhandlungen 171 199-2131996Itrongay, Madagascar0293
CIF Raw Data - click here to close

X-Ray Powder DiffractionHide

Image Loading

Radiation - Copper Kα
Data Set:
Data courtesy of RRUFF project at University of Arizona, used with permission.
Powder Diffraction Data:
d-spacingIntensity
4.22 Å(70)
3.77 Å(80)
3.47 Å(45)
3.31 Å(100)
3.29 Å(60)
3.24 Å(65)
2.992 Å(50)
Comments:
ICDD 19-931

Geological EnvironmentHide

Paragenetic Mode(s):
Paragenetic ModeEarliest Age (Ga)
Stage 3a: Earth’s earliest Hadean crust>4.50
9 : Lava/xenolith minerals (hornfels, sanidinite facies)
Stage 3b: Earth’s earliest hydrosphere>4.45
17 : Marine authigenic Hadean minerals (see also #24)
Stage 4a: Earth’s earliest continental crust>4.4-3.0
19 : Granitic intrusive rocks
Near-surface Processes
22 : Hydration and low-𝑇 subsurface aqueous alteration (see also #23)
23 : Subaerial aqueous alteration by non-redox-sensitive fluids (see also #47)
24 : Authigenic minerals in terrestrial sediments (see also #17)
26 : Hadean detrital minerals
Stage 4b: Highly evolved igneous rocks>3.0
34 : Complex granite pegmatites
35 : Ultra-alkali and agpaitic igneous rocks
Stage 5: Initiation of plate tectonics<3.5-2.5
40 : Regional metamorphism (greenschist, amphibolite, granulite facies)
Geological Setting:
Common feldspar of high-temperature granites, syenites, high-grade metamorphic rocks, and some felsic extrusive rocks, eg some rhyolites (although these tend to contain sanidine when fresh).

Synonyms of OrthoclaseHide

Other Language Names for OrthoclaseHide

Varieties of OrthoclaseHide

AglauriteA variety of Orthoclase feldspar with a blue reflection.
Originally described from Teplice (Teplitz), Ústí Region, Bohemia (Böhmen; Boehmen), Czech Republic.
Arsenic-bearing OrthoclaseAs-bearing orthoclase variety from Tolbachik volcano (Arsenatnaya and Yadovitaya fumaroles). Compare filatovite.
Barium-OrthoclaseA Ba-bearing orthoclase with K:Ba > 6.
Barium-bearing Orthoclase
DelawariteA variety of orthoclase with a pearly lustre.
Na-orthoclaseDescribed as a Na- rich orthoclase or cryptoperthite; possibly actually Sanidine.
ParadoxiteAn obsolete name for flesh-coloured orthoclase occurring in hydrothermal veins, originally described from the tin mines near Marienberg, Saxony, Germany by A. Breithaupt in 1866 (Berg. Hüt., xxv, 35. as 'paradoxit')
Rainbow Lattice SunstoneA variety of orthoclase with unusual crystallographically-oriented inclusions of magnetite, haematite and biotite.

Relationship of Orthoclase to other SpeciesHide

Common AssociatesHide

Associated Minerals Based on Photo Data:
544 photos of Orthoclase associated with QuartzSiO2
362 photos of Orthoclase associated with Smoky QuartzSiO2
223 photos of Orthoclase associated with AlbiteNa(AlSi3O8)
171 photos of Orthoclase associated with MuscoviteKAl2(AlSi3O10)(OH)2
167 photos of Orthoclase associated with SchorlNaFe2+3Al6(Si6O18)(BO3)3(OH)3(OH)
165 photos of Orthoclase associated with FluoriteCaF2
156 photos of Orthoclase associated with AegirineNaFe3+Si2O6
113 photos of Orthoclase associated with SpessartineMn2+3Al2(SiO4)3
113 photos of Orthoclase associated with AquamarineBe3Al2Si6O18
102 photos of Orthoclase associated with Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)

Related Minerals - Strunz-mindat GroupingHide

9.FA.HexacelsianBaAl2Si2O8Hex. 6/mmm (6/m 2/m 2/m) : P63/mcm
9.FA.Wodegongjieite KCa3(Al7Si9)O32Hex. 6/mmm (6/m 2/m 2/m) : P6/mcc
9.FA.05KaliophiliteKAlSiO4Trig. 3 : P3
9.FA.05KalsiliteKAlSiO4Hex. 6 2 2 : P63 2 2
9.FA.05NephelineNa3K(Al4Si4O16)Hex. 6 : P63
9.FA.05Panunzite(K,Na)AlSiO4Hex. 6 : P63
9.FA.05TrikalsiliteK2NaAl3(SiO4)3Hex. 6 : P63
9.FA.05Yoshiokaite(Ca,Na)[Al(Al,Si)O4]Trig. 3 : P3
9.FA.05CarnegieiteNaAlSiO4Tric.
9.FA.05 vaGermanate-nepheline(Na,K)AlGeO4
9.FA.05MegakalsiliteKAlSiO4Hex. 6 : P63
9.FA.05TrinephelineNaAlSiO4 Hex. 6 : P61
9.FA.05Davidsmithite(Ca,◻)2Na6Al8Si8O32Hex. 6 : P63
9.FA.10MalinkoiteNaBSiO4Hex. 6 : P63
9.FA.15VirgiliteLiAlSi2O6Hex. 6 2 2 : P62 2 2
9.FA.25LisitsyniteKBSi2O6Orth. 2 2 2 : P2 2 2
9.FA.30Buddingtonite(NH4)(AlSi3O8)Mon. 2 : P21
9.FA.30CelsianBa(Al2Si2O8)Mon. 2/m
9.FA.30MicroclineK(AlSi3O8)Tric. 1
9.FA.30SanidineK(AlSi3O8)Mon. 2/m : B2/m
9.FA.30RubiclineRb(AlSi3O8)Mon. 2/m : B2/m
9.FA.30 vaGermanate-celsianBaAl2Ge2O8
9.FA.30MonalbiteNaAlSi3O8Mon. 2/m : B2/m
9.FA.30FerrisanidineK[Fe3+Si3O8]Mon. 2/m : B2/m
9.FA.35AlbiteNa(AlSi3O8)Tric. 1
9.FA.35AnorthiteCa(Al2Si2O8)Tric. 1 : P1
9.FA.35ReedmergneriteNaBSi3O8Tric. 1 : P1
9.FA.40ParacelsianBa(Al2Si2O8)Mon. 2/m : P21/b
9.FA.45SvyatoslaviteCa(Al2Si2O8)Mon. 2 : P21
9.FA.45KumdykoliteNa(AlSi3O8)Orth. mmm (2/m 2/m 2/m) : Pnnm
9.FA.50SlawsoniteSr(Al2Si2O8)Mon. 2/m : P21/b
9.FA.55LisetiteCaNa2Al4Si4O16Orth. mm2
9.FA.60BanalsiteNa2BaAl4Si4O16Orth. mm2 : Iba2
9.FA.60StronalsiteNa2SrAl4Si4O16Orth.
9.FA.65DanburiteCaB2Si2O8Orth. mmm (2/m 2/m 2/m)
9.FA.65MaleeviteBaB2Si2O8Orth. mmm (2/m 2/m 2/m) : Pnma
9.FA.65PekoviteSrB2Si2O8Orth. mmm (2/m 2/m 2/m) : Pnma
9.FA.70StöffleriteCaAl2Si2O8Tet. 4/m : I4/m
9.FA.70Lingunite(Na,Ca)AlSi3O8Tet. 4/m : I4/m
9.FA.70LiebermanniteKAlSi3O8Tet. 4/m : I4/m
9.FA.75KokchetaviteK(AlSi3O8)Hex. 6/mmm (6/m 2/m 2/m) : P6/mcc
9.FA.75Pfaffenbergite KNa3(Al4Si12)O32Hex. 6/mmm (6/m 2/m 2/m) : P6/mcc

Fluorescence of OrthoclaseHide

In UV light:
May fluoresce dull white or red in SW UV

Other InformationHide

Health Risks:
No information on health risks for this material has been entered into the database. You should always treat mineral specimens with care.
Industrial Uses:
Ceramics, abrasives, crushed stone, decorative facing in slabbed rock panels, gem materials

Orthoclase in petrologyHide

Internet Links for OrthoclaseHide

References for OrthoclaseHide

Reference List:
Liu, J., Shen, A. H., Zhang, Z., Wang, C., and Shao, T.: Revisiting Rainbow Lattice Sunstone from the Harts Range, Australia, J. Gemmol., 36, 44–52, 2018. https://www.mindat.org/reference.php?id=1081966
Coombs, D.S. (1954) Ferriferous orthoclase from Madagascar. Mineralogical Magazine: 30: 409-427.
Brace, W. F., Walsh, J. B. (1962) Some direct measurements of the surface energy of quartz and orthoclase. American Mineralogist, 47 (9-10) 1111-1122
Wright, T.L., Stewart, D.B. (1968) X-ray and optical study of alkali feldspar, I. Determination of composition and structural state from refined unit-cell parameters and 2Y. American Mineralogist: 53: 38-87.
Prince, E., Donnay, G., Martin, R.F. (1973) Neutron diffraction refinement of an ordered orthoclase structure. American Mineralogist: 58: 500-507.
Foland, K.A. (1974) 40Ar diffusion in homogeneous orthoclase and an interpretation of Ar diffusion in K-feldspar. Geochimica et Cosmochimica Acta: 3: 151-166.
(1977) Mineralogical Record: 8: 363.
Eggleton, R.A., Buseck, P.R. (1980) The orthoclase-microcline inversion: A high-resolution transmission electron microscope study and strain analysis. Contributions to Mineralogy and Petrology: 74: 123-133.
Priess, U. (1981) Untersuchungen zur Tief-Hoch-Umwandlung von Fe-haltingen Orthoklas-Kristallen aus Madagaskar. Neues Jahrbuch für Mineralogie, Abhandlungen: 141: 17-29.
Goldsmith, J. (1988) Enhanced Al/Si diffusion in KAlSi3O8 at high pressures: the effect of hydrogen. Journal of Geology: 96: 109-124.
Foland, K.A. and Xu, Y.-P. (1990) Diffusion of 40Ar and 39Ar in irradiated orthoclase. Geochimica et Cosmochimica Acta: 54: 3147-3158.
Widder, W. (1991) Röntgentopographische Untersuchungen am Sanidin von Volkesfeld und Orthoklas von Madagaskar. Diplomarbeit, Fakultät für Physik, Universität Karlsruhe, Karlsruhe, Germany, xx pp (in German).
Waldron, K.A., Parsons, I., Brown, W.L. (1993) Solution-redeposition and the orthoclase-microcline transformation: evidence from granulites and relevance to 18O exchange. Mineralogical Magazine: 57: 687-695.
Acta Crystallographica (1995): A53.
Anthony, John Williams, Bideaux, Richard A., Bladh, Kenneth W., Nichols, Monte C. (1995) Handbook of Mineralogy Vol. 2 part 1 - Silica, Silicates. Mineral Data Publishing, Tucson, Arizona.p.606
Kimata, M., Saito, S., Shimizu, M., Iida, I., Tomoaki, M. (1996) Low-temperature crystal structures of orthoclase and sanidine. Neues Jahrbuch für Mineralogie, Abhandlungen: 171: 199-213.
Villa, I.M. (1996) The influence of irradiation and heating schedule on Ar diffusion in gem-quality orthoclase from Madagascar. Journal Conf. Abstr.: 1(1): 652.
Arnaud, N.O., Kelley, S.P. (1997) Argon behaviour in gem-quality orthoclase from Madagascar: experiments and some consequences for 40Ar/39Ar geochronology. Geochimica et Cosmochimica Acta: 61: 3227-3255.
Fenter, P., Teng, H., Geissbühler, P., Hanchar, J.M., Nagy, K., Sturchio, N.C. (2000) Atomic-scale structure of the orthoclase (001) - water interface measured with high-resolution X-ray reflectivity. Geochimica et Cosmochimica Acta: 64: 3663-3673.
Teng, H.H., Fenter, P., Cheng, L., Sturchio, N.C. (2001) Resolving orthoclase dissolution processes with atomic force microscopy and X-ray reflectivity. Geochimica et Cosmochimica Acta: 65: 3459-3474.
(2023) Orthoclase. Handbook of Mineralogy. Mineralogical Society of America

Localities for OrthoclaseHide

This map shows a selection of localities that have latitude and longitude coordinates recorded. Click on the symbol to view information about a locality. The symbol next to localities in the list can be used to jump to that position on the map.

Locality ListShow

This section is currently hidden. Click the show button to view.
Quick NavTopAbout OrthoclaseUnique IdentifiersIMA Classification Classification Mineral SymbolsPronunciation Physical Properties Optical Data Chemistry Crystallography Crystallographic forms Crystal StructureX-Ray Powder DiffractionGeological EnvironmentSynonymsOther LanguagesVarietiesRelationshipsCommon AssociatesStrunz-MindatFluorescence Other InformationOrthoclase in petrologyInternet Links References Localities Locality List
 
Mineral and/or Locality  
Mindat Discussions Facebook Logo Instagram Logo Discord Logo
Mindat.org is an outreach project of the Hudson Institute of Mineralogy, a 501(c)(3) not-for-profit organization.
Copyright © mindat.org and the Hudson Institute of Mineralogy 1993-2024, except where stated. Most political location boundaries are © OpenStreetMap contributors. Mindat.org relies on the contributions of thousands of members and supporters. Founded in 2000 by Jolyon Ralph.
Privacy Policy - Terms & Conditions - Contact Us / DMCA issues - Report a bug/vulnerability Current server date and time: April 24, 2024 16:49:45 Page updated: April 24, 2024 01:26:19
Go to top of page