Goethite X050091

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Record 1666 of 4216  
Name: Goethite
RRUFF ID: X050091
Ideal Chemistry: FeO(OH)
Locality: Michigan, USA
Source: Caltech
Owner: Caltech
Description:
Status: The identification of this mineral has been determined only by Raman spectroscopy
Mineral Group: [ Diaspore (11) ]
Quick search: [ All Goethite samples (4) ]
RAMAN SPECTRUM 
Sample Description: de-polarized laser oriented parallel to the c axis
X Min:    X Max:    X Sort:
REFERENCES for Goethite

American Mineralogist Crystal Structure Database Record: [view record]

Anthony J W, Bideaux R A, Bladh K W, and Nichols M C (1990) Handbook of Mineralogy, Mineral Data Publishing, Tucson Arizona, USA, by permission of the Mineralogical Society of America. [view file]

Lenz J G (1806) Göthit, in Tabellen über das gesammte Mineralreich Göpferdts Jena 46-46

Posnjak E, Merwin H E (1919) The hydrated ferric oxides, American Journal of Science, 47, 311-348   [view file]

Spencer L J (1919) Mineralogical characters of turite (=turgite) and some other iron-ores from Nova Scotia, Mineralogical Magazine, 18, 339-348   [view file]

Hoppe W (1940) Über die kristallstruktur von α-AlOOH (diaspor) und α-FeOOH (nadeleisenerz), Zeitschrift für Kristallographie, 103, 73-89   [view file]

Bernal J D, Dasgupta D R, Mackay A L (1959) The oxides and hydroxides of iron and their structural inter-relationships, Clay Minerals Bulletin, 4, 15-30

Gorton A T, Bitsianes G, Joseph T L (1965) Thermal expansion coefficients for iron and its oxides from X-ray diffraction measurements at elevated temperatures, Transactions of the Metallurgical Society of AIME, 233, 1519-1525

Szytula A, Burewicz A, Dimitrijevic Z, Krasnicki S, Rzany H, Todorovic J, Wanic A, Wolski W (1968) Neutron Diffraction Studies of α-FeOOH, Physica Status Solidi, 26, 429-434

Cech F, Johan Z (1969) Identité de l´allcharite et de la goethite, Bulletin de la Société Française de Minéralogie et de Cristallographie, 92, 99-100   [view file]

International Mineralogical Association (1980) International Mineralogical Association: Commission on new minerals and mineral names, Mineralogical Magazine, 43, 1053-1055   [view file]

Schwertmann U, Murad E (1983) Effect of pH on the formation of goethite and hematite from ferrihydrite, Clays and Clay Minerals, 31, 277-284   [view file]

Wolska E, Schwertmann U (1989) Nonstoichiometric structures during dehydroxylation of goethite, Zeitschrift für Kristallographie, 189, 223-237   [view file]

Cornell R M, Giovanoli R (1991) Transformation of akaganéite into goethite and hematite in the presence of Mn, Clays and Clay Minerals, 39, 144-150   [view file]

de Faria D L A, Silva S V, de Oliveira M T (1997) Raman microspectroscopy of some iron oxides and oxyhydroxides, Journal of Raman Spectroscopy, 28, 873-878   [link]

Oh S J, Cook D C, Townsend H E (1998) Characterization of iron oxides commonly formed as corrosion products on steel, Hyperfine Interactions, 112, 59-65   [link]

Gualtieri A F, Venturelli P (1999) In situ study of the goethite-hematite phase transformation by real time synchrotron powder diffraction, American Mineralogist, 84, 895-904   [view file]

Shannon R D, Shannon R C, Medenbach O, Fischer R X (2002) Refractive index and dispersion of fluorides and oxides, Journal of Physical and Chemical Reference Data, 31, 931-970   [view file]

Frankel R B, Bazylinski D A (2003) Biologically induced mineralization by bacteria, Reviews in Mineralogy and Geochemistry, 54, 95-114

Hamilton V E, McSween H Y, Hapke B (2005) Mineralogy of Martian atmospheric dust inferred from thermal infrared spectra of aerosols, Journal of Geophysical Research, 110, E12006   [link]

Yang H, Lu R, Downs R T, Costin G (2006) Goethite, α–FeO(OH), from single–crystal data, Acta Crystallographica, E62, i250-i252   [view file]

Faria D L A, Lopes F N (2007) Heated goethite and natural hematite: can Raman spectroscopy be used to differentiate them?, Vibrational Spectroscopy, 45, 117-121

Alvarez M, Sileo E E, Rueda E H (2008) Structure and reactivity of synthetic Co-substituted goethites, American Mineralogist, 93, 584-590   [view file]

Kučerová G, Majzlan J, Lalinská-Voleková B, Radková A, Bačík P, Michňová J, Šottník P, Jurkovič L, Klimko T, Steininger R, Göttlicher J (2014) Mineralogy of neutral mine drainage in the tailings of siderite-Cu ores in eastern Slovakia, The Canadian Mineralogist, 52, 779-798

Sobron P, Bishop J L, Blake D F, Chen B, Rull F (2014) Natural Fe-bearing oxides and sulfates from the Rio Tinto Mars analog site: Critical assessment of VNIR reflectance spectroscopy, laser Raman spectroscopy, and XRD as mineral identification tools, American Mineralogist, 99, 1199-1205

Wang M, Chou I, Lu W, de Vivo B (2015) Effects of CH4 and CO2 on the sulfidization of goethite and magnetite: an in situ Raman spectroscopic study in high-pressure capillary optical cells at room temperature, European Journal of Mineralogy, 27, 193-201

Kreissl S, Bolanz R, Göttlicher J, Steininger R, Tarassov, Markl G (2016) Structural incorporation of W6+ into hematite and goethite: A combined study of natural and synthetic iron oxides developed from precursor ferrihydrite and the preservation of ancient fluid compositions in hematite, American Mineralogist, 101, 2701-2715

Negrão L B A, Da Costa M L, Pöllmann H, Horn A (2018) An application of the Rietveld refinement method to the mineralogy of a bauxite-bearing regolith in the Lower Amazon, Mineralogical Magazine, 82, 413-431

Voelz J L, Arnold W A, Penn R L (2018) Redox-induced nucleation and growth of goethite on synthetic hematite nanoparticles, American Mineralogist, 103, 1021-1029

Markl G, Keim M F, Bayerl R (2019) Unusual mineral diversity in hydrothermal vein-type deposit: The Clara mine, SW Germany, as a type example, The Canadian Mineralogist, 57, 427-456

Heaney P J, Oxman M J, Chen S A (2020) A structural study of size-dependent lattice variation: In situ X-ray diffraction of the growth of goethite nanoparticles from 2-line ferrihydrite, American Mineralogist, 105, 652-663