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![Polyhedral representation of the [Bi(SO4)2]− layers in markhininite (b) and [Fe(SO4)2]− in yavapaiite (e) and their graphs (a, d). The bidentate linkage between the BiO8 polyhedron and SO4 tetrahedra in markhininite (c) and monodentate linkage between the FeO6 and SO4 in yavapaiite (f) are highlighted. A polyhedral representation of interlayer formed by TlO14 polyhedra (g) and comparison of Tl+ cation packing in markhininite and K+ packing in yavapaiite (h) is shown.]()
![Heteropolyhedral yavapaiite-related layers in minerals and synthetic compounds: (a) yavapaiite KFe(SO4)2, (b) embreyite, (c) bütschliite K2Ca(CO3)2, (d) markhininite TlBi(SO4)2, (e) K2Mn(SeO3)2 and (f) RbSc(SeO3)2. Black arrows designate the orientation of TO4 tetrahedra or SeO3 groups in a direction towards or outwards from the layer. See the text for details.]()
![The yavapaiite-related ZrO6-PO4 octahedral-tetrahedral layer parallel to (001) in wycheproofite. All drawings were done with ATOMS (Shape Software, 1999).]()
![(a) Mid-infrared thermal emissivity spectra of sulfates with sheets of SO4 tetrahedra and MX6 octahedra, and their crystal structure diagrams—including goldichite (Graeber and Rosenzweig 1971), kornelite (Robinson and Fang 1973), rhomboclase (Mereiter 1974), slavikite (Parafiniuk et al. 2010), and yavapaiite (Graeber and Rosenzweig 1971). Band depths have been adjusted by multiplying the spectra by the parenthetical amounts; spectra are then offset for clarity. (b) VNIR reflectance spectra from 0.4–5 μm of sulfates with sheets of SO4 tetrahedra and MX6 octahedra including rhomboclase, yavapaiite, slavikite, kornelite, and goldichite. The slavikite spectrum is offset for clarity.]()
![SEM–BSE image of crystals of aluminocoquimbite, associated with tamarugite (platy crystals, top left) and yavapaiite (light gray crystals, right).]()
![(a) The [Mg(SiO4)2] sheet in merwinite; (b) the [Fe3+(SO4)2] sheet in yavapaiite; legend as in Fig. 1.]()
![Hyperspectral VNIR reflectance spectra of sulfate and phosphate minerals: ferricopiapite ML-S35, fibroferrite SPT121, (para)coquimbite ML-S46, jarosite JB53, rhomboclase 81268, kornelite R16185, yavapaiite ML-S79, ferristrunzite HMM108175, wavellite ML-P9, and scholzite ML-P11.]()
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![Pancam I/F spectra of Paso Robles end-members compared to laboratory reflectance spectra of sulfate and phosphate minerals. Three end-member spectra are shown from the sol 400 and sol 426 unmixing analyses that represent the white/yellow/pink colored bright soils shown in Figure 1. The laboratory spectra were convolved to the 11 Pancam channels and include ferricopiapite ML-S35, fibroferrite SPT121, (para)coquimbite ML-S46, jarosite JB53, rhomboclase 81268, kornelite R16185, yavapaiite ML-S79, ferristrunzite HMM108175, wavellite ML-P9, and scholzite ML-P11.]()
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![Diagram of the stoichiometries for Fe-sulfate and Fe-(hydr)oxide minerals (modified after Jerz and Rimstidt 2003; King and McSween 2005; Lane et al. 2008). The minerals examined in this paper are in bold. The general trend for AMD sites is shown as Path i (Jerz and Rimstidt 2003) and Path ii is proposed for Mars (King and McSween 2005). The mineral abbreviations are: halotrichite (Hal), melanterite (Mel), ferrohexahydrite (Fhex), siderotil (Sidt), rozenite (Roz), szomolnokite (Szom), bilinite (Bil), römerite (Rom), slavikite (Sla), botryogen (Bot), voltaite (Vol), copiapite (Cop), ferricopiapite (Fcop), fibroferrite (Fib), hohmannite (Hoh), amarantite (Amar), butlerite and parabutlerite (But), metahohmannite (Mhoh), quenstedtite (Que), paracoquimbite (Pcoq), goldichite (Gol), kornelite (Kor), lausenite (Lau), ferrinatrite (Fnat), metavoltine (Metv), krausite (Kra), rhomboclase (Rhom), yavapaiite (Yav), jarosite (Jrs), schwertmannite (Schwrt), ferrihydrite (Fer), goethite (Goe), hematite (Hem), and maghemite (Magh).]()
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yavapaiite
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Journal Article
The Crystal Structures of Yavapaiite, KFe(SO 4 ) 2 , And Goldichite, KFe(SO 4 ) 2 ·4H 2 O Available to Purchase
Journal: American Mineralogist
Publisher: Mineralogical Society of America
Published: 01 December 1971
American Mineralogist (1971) 56 (11-12): 1917–1933.
...Edward J. Graeber; Abraham Rosenzweig Abstract Yavapaiite [KFe(SO 4 ) 2 ] crystallizes in space group C2 / m with two formula weights in a unit cell of dimensions a = 8.152, b = 5.153, c = 7.877 Å, β = 94.90°. The structure was solved by a three-dimensional Patterson synthesis and refined...
Journal Article
Yavapaiite, an Anhydrous Potassium, Ferric Sulphate from Jerome, Arizona Available to Purchase
Journal: American Mineralogist
Publisher: Mineralogical Society of America
Published: 01 December 1959
American Mineralogist (1959) 44 (11-12): 1105–1114.
...C. Osborne Hutton Abstract Yavapaiite, a new mineral from Jerome, Arizona, has the composition KFe 3+ (SO 4 ) 2 with two formula units in the unit cell. The mineral, associated with sulphur, voltaite, and other unidentified sulphates, forms pale pink, brittle, adamantine crystals, elongate parallel...
Image
![Polyhedral representation of the [Bi(SO4)2]− layers in markhininite (b) and [Fe(SO4)2]− in yavapaiite (e) and their graphs (a, d). The bidentate linkage between the BiO8 polyhedron and SO4 tetrahedra in markhininite (c) and monodentate linkage between the FeO6 and SO4 in yavapaiite (f) are highlighted. A polyhedral representation of interlayer formed by TlO14 polyhedra (g) and comparison of Tl+ cation packing in markhininite and K+ packing in yavapaiite (h) is shown.](https://gsw.silverchair-cdn.com/gsw/Content_public/Journal/minmag/78/7/10.1180_minmag.2014.078.7.12/3/s_12_sii_06.jpeg?Expires=2147483647&Signature=C0OaQWJC1J4mmr~IiPvTBekIGWtQsDMloqUVOcVElMIP7jJAkYfwtfbEByHnTYZHxiMXzfazkWeEzwIy~hSarHFfk79PEbC2GVBx1LEz3R8BdPqtjRQwoeygN2Jd~G2szCM7~1-2XebhL-kQjPLwVh3Vm9ctXTSnofDa~nUEWpgX~gsyo1rsm5GArlCkrUoGp4qCYeXWy6SnQZu5NicbUBY8oRm87bLNxenyuoOUKWF2xirtdZYw8TPJwyWYCQZ-7tPGDdTw4-6ZVK1RdyJDDO6u4TGL1t7q2PO-6ZdMjNxCrl~swn2Lnxw0vqB7unhP-1szuy0Iyw-o9dcQ5XJICQ__&Key-Pair-Id=APKAIE5G5CRDK6RD3PGA)
Polyhedral representation of the [Bi(SO 4 ) 2 ] − layers in markhininite (... Available to Purchase
in Unique thallium mineralization in the fumaroles of Tolbachik volcano, Kamchatka Peninsula, Russia. I. Markhininite, TlBi(SO 4 ) 2
> Mineralogical Magazine
Published: 01 December 2014
F ig . 6. Polyhedral representation of the [Bi(SO 4 ) 2 ] − layers in markhininite ( b ) and [Fe(SO 4 ) 2 ] − in yavapaiite ( e ) and their graphs ( a, d ). The bidentate linkage between the BiO 8 polyhedron and SO 4 tetrahedra in markhininite ( c ) and monodentate linkage between the FeO 6
Image
Heteropolyhedral yavapaiite-related layers in minerals and synthetic compou... Available to Purchase
in Embreyite: structure determination, chemical formula and comparative crystal chemistry
> Mineralogical Magazine
Published: 01 April 2018
Fig. 6. Heteropolyhedral yavapaiite-related layers in minerals and synthetic compounds: ( a ) yavapaiite KFe(SO 4 ) 2 , ( b ) embreyite, ( c ) bütschliite K 2 Ca(CO 3 ) 2 , ( d ) markhininite TlBi(SO 4 ) 2 , ( e ) K 2 Mn(SeO 3 ) 2 and (f) RbSc(SeO 3 ) 2 . Black arrows designate the orientation
Image
The yavapaiite-related ZrO 6 -PO 4 octahedral-tetrahedral layer parallel t... Available to Purchase
in The crystal structure of wycheproofite, NaAlZr(PO 4 ) 2 (OH) 2 ·H 2 O
> European Journal of Mineralogy
Published: 01 November 2003
Fig. 1. The yavapaiite-related ZrO 6 -PO 4 octahedral-tetrahedral layer parallel to (001) in wycheproofite. All drawings were done with ATOMS ( Shape Software, 1999 ).
Image
( a ) Mid-infrared thermal emissivity spectra of sulfates with sheets of SO... Available to Purchase
in Mid-infrared emission spectroscopy and visible/near-infrared reflectance spectroscopy of Fe-sulfate minerals
> American Mineralogist
Published: 01 January 2015
( Parafiniuk et al. 2010 ), and yavapaiite ( Graeber and Rosenzweig 1971 ). Band depths have been adjusted by multiplying the spectra by the parenthetical amounts; spectra are then offset for clarity. ( b ) VNIR reflectance spectra from 0.4–5 μm of sulfates with sheets of SO 4 tetrahedra and MX 6 octahedra
Image
SEM–BSE image of crystals of aluminocoquimbite, associated with tamarugite ... Available to Purchase
in ALUMINOCOQUIMBITE, AlFe(SO 4 ) 3 ·9H 2 O, A NEW ALUMINUM IRON SULFATE FROM GROTTA DELL’ALLUME, VULCANO, AEOLIAN ISLANDS, ITALY
> The Canadian Mineralogist
Published: 01 December 2010
F ig . 1. SEM–BSE image of crystals of aluminocoquimbite, associated with tamarugite (platy crystals, top left) and yavapaiite (light gray crystals, right).
Image
![(a) The [Mg(SiO4)2] sheet in merwinite; (b) the [Fe3+(SO4)2] sheet in yavapaiite; legend as in Fig. 1.](https://gsw.silverchair-cdn.com/gsw/Content_public/Journal/minmag/74/3/10.1180_minmag.2010.074.3.567/3/s_14-haw-05.jpeg?Expires=2147483647&Signature=eh5d43SKjSc0JWsnxoDbxVsafcUi5iScYkvF7wj~GGIlSfnJ9SCQUownURSf87MOvFu1fznUCwcV1nfhtwYGgSrYLuoTK2Ik2MqOAOuRfFOMmS808Gjrjtj3Qks1UwybiOorou4BA3oWfkbifXjx2EvINQ2MCln-AdVzFQWHXQlJ8hWTmN-vXtQV19~vf1pFLcaH3L62g3UIhPHxcNDK~YQ3lElFOS4P1LFdAp-7oCh88D2wr-TxVSDA2uMK-L-Cf2MmXKJuLpFAYCE8C4E6UuciMb1gOLrOMLAZHsfNrhnJ39RIIN5~Ve5TK~NVGISIGvlAsQwW694tZ6K4lmWStQ__&Key-Pair-Id=APKAIE5G5CRDK6RD3PGA)
( a ) The [Mg(SiO 4 ) 2 ] sheet in merwinite; ( b ) the [Fe 3+ (SO 4 ) 2 ] ... Available to Purchase
in The crystal structure of zigrasite, MgZr(PO 4 ) 2 (H 2 O) 4 , a heteropolyhedral framework structure
> Mineralogical Magazine
Published: 01 June 2010
F ig . 5. ( a ) The [Mg(SiO 4 ) 2 ] sheet in merwinite; ( b ) the [Fe 3+ (SO 4 ) 2 ] sheet in yavapaiite; legend as in Fig. 1 .
Image
Hyperspectral VNIR reflectance spectra of sulfate and phosphate minerals: f... Available to Purchase
Published: 01 May 2008
F igure 4. Hyperspectral VNIR reflectance spectra of sulfate and phosphate minerals: ferricopiapite ML-S35, fibroferrite SPT121, (para)coquimbite ML-S46, jarosite JB53, rhomboclase 81268, kornelite R16185, yavapaiite ML-S79, ferristrunzite HMM108175, wavellite ML-P9, and scholzite ML-P11.
Journal Article
Embreyite: structure determination, chemical formula and comparative crystal chemistry Available to Purchase
Journal: Mineralogical Magazine
Published: 01 April 2018
Mineralogical Magazine (2018) 82 (2): 275–290.
...Fig. 6. Heteropolyhedral yavapaiite-related layers in minerals and synthetic compounds: ( a ) yavapaiite KFe(SO 4 ) 2 , ( b ) embreyite, ( c ) bütschliite K 2 Ca(CO 3 ) 2 , ( d ) markhininite TlBi(SO 4 ) 2 , ( e ) K 2 Mn(SeO 3 ) 2 and (f) RbSc(SeO 3 ) 2 . Black arrows designate the orientation...
FIGURES
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Journal Article
Magnesiovoltaite, K 2 Mg 5 Fe 3+ 3 Al(SO 4 ) 12 ·18H 2 O, a new mineral from the Alcaparrosa mine, Antofagasta region, Chile Available to Purchase
Journal: European Journal of Mineralogy
Publisher: GeoScienceWorld Journals
Published: 01 December 2016
European Journal of Mineralogy (2016) 28 (5): 1005–1017.
... Alcaparrosa, El Loa province, Antofagasta region, Chile, in two associations, one of which includes coquimbite, tamarugite, alum-(Na), rhomboclase, yavapaiite, voltaite and opal, and the other one is botryogen, opal, tamarugite, alum-(K), pickeringite, magnesiocopiapite, and jarosite. Magnesiovoltaite forms...
FIGURES
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Includes: Supplemental Content
Journal Article
Unique thallium mineralization in the fumaroles of Tolbachik volcano, Kamchatka Peninsula, Russia. I. Markhininite, TlBi(SO 4 ) 2 Available to Purchase
Journal: Mineralogical Magazine
Published: 01 December 2014
Mineralogical Magazine (2014) 78 (7): 1687–1698.
...F ig . 6. Polyhedral representation of the [Bi(SO 4 ) 2 ] − layers in markhininite ( b ) and [Fe(SO 4 ) 2 ] − in yavapaiite ( e ) and their graphs ( a, d ). The bidentate linkage between the BiO 8 polyhedron and SO 4 tetrahedra in markhininite ( c ) and monodentate linkage between the FeO 6...
FIGURES
| View All (7)
Journal Article
ALUMINOCOQUIMBITE, AlFe(SO 4 ) 3 ·9H 2 O, A NEW ALUMINUM IRON SULFATE FROM GROTTA DELL’ALLUME, VULCANO, AEOLIAN ISLANDS, ITALY Available to Purchase
Journal: The Canadian Mineralogist
Publisher: Mineralogical Association of Canada
Published: 01 December 2010
The Canadian Mineralogist (2010) 48 (6): 1465–1468.
...F ig . 1. SEM–BSE image of crystals of aluminocoquimbite, associated with tamarugite (platy crystals, top left) and yavapaiite (light gray crystals, right). ...
FIGURES
Journal Article
Eldfellite, NaFe(SO 4 ) 2 , a new fumarolic mineral from Eldfell volcano, Iceland Available to Purchase
Journal: Mineralogical Magazine
Published: 01 February 2009
Mineralogical Magazine (2009) 73 (1): 51–57.
.... The calculated density is 3.062 g/cm 3 . Eldfellite is monoclinic, C 2/ m, a 8.043(4) Å, b 5.139(2) Å, c 7.115(4) Å, β 92.13(2)°, V uc 293.9(2) Å 3 , Z = 2 and is isostructural with yavapaiite [KFe(SO 4 ) 2 ]. The strongest lines in the powder diffraction diagram are [ d (Å), I (relative to 10)]: 3.72, 8...
FIGURES
Journal Article
The crystal structure of wycheproofite, NaAlZr(PO 4 ) 2 (OH) 2 ·H 2 O Available to Purchase
Journal: European Journal of Mineralogy
Publisher: GeoScienceWorld Journals
Published: 01 November 2003
European Journal of Mineralogy (2003) 15 (6): 1029–1034.
...Fig. 1. The yavapaiite-related ZrO 6 -PO 4 octahedral-tetrahedral layer parallel to (001) in wycheproofite. All drawings were done with ATOMS ( Shape Software, 1999 ). ...
FIGURES
Journal Article
The Crystal Structure of Yayapaiite: A Discussion Available to Purchase
Journal: American Mineralogist
Publisher: Mineralogical Society of America
Published: 01 October 1972
American Mineralogist (1972) 57 (9-10): 1546–1549.
...John W. Anthony; W. John McLean; Robert B. Latjghon Abstract The crystal structure of yavapaiite, recently determined by Graeber and Rosenzweig (1972), is shown to be similar to those of FeS0 4 and Na2S0 4 (III). Crystal data and atomic parameters determined in this study are presented. Copyright...
Journal Article
Mid-infrared emission spectroscopy and visible/near-infrared reflectance spectroscopy of Fe-sulfate minerals Available to Purchase
Journal: American Mineralogist
Publisher: Mineralogical Society of America
Published: 01 January 2015
American Mineralogist (2015) 100 (1): 66–82.
... ( Parafiniuk et al. 2010 ), and yavapaiite ( Graeber and Rosenzweig 1971 ). Band depths have been adjusted by multiplying the spectra by the parenthetical amounts; spectra are then offset for clarity. ( b ) VNIR reflectance spectra from 0.4–5 μm of sulfates with sheets of SO 4 tetrahedra and MX 6 octahedra...
FIGURES
| View All (6)
Includes: Supplemental Content
Image
Pancam I/F spectra of Paso Robles end-members compared to laboratory reflec... Available to Purchase
Published: 01 May 2008
. The laboratory spectra were convolved to the 11 Pancam channels and include ferricopiapite ML-S35, fibroferrite SPT121, (para)coquimbite ML-S46, jarosite JB53, rhomboclase 81268, kornelite R16185, yavapaiite ML-S79, ferristrunzite HMM108175, wavellite ML-P9, and scholzite ML-P11.
Journal Article
Mineralogy of the Paso Robles soils on Mars Available to Purchase
Journal: American Mineralogist
Publisher: Mineralogical Society of America
Published: 01 May 2008
American Mineralogist (2008) 93 (5-6): 728–739.
...F igure 4. Hyperspectral VNIR reflectance spectra of sulfate and phosphate minerals: ferricopiapite ML-S35, fibroferrite SPT121, (para)coquimbite ML-S46, jarosite JB53, rhomboclase 81268, kornelite R16185, yavapaiite ML-S79, ferristrunzite HMM108175, wavellite ML-P9, and scholzite ML-P11. ...
FIGURES
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Image
Diagram of the stoichiometries for Fe-sulfate and Fe-(hydr)oxide minerals (... Available to Purchase
in Methods to analyze metastable and microparticulate hydrated and hydrous iron sulfate minerals
> American Mineralogist
Published: 01 November 2011
), yavapaiite (Yav), jarosite (Jrs), schwertmannite (Schwrt), ferrihydrite (Fer), goethite (Goe), hematite (Hem), and maghemite (Magh).
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