The lepidocrocite-maghemite-haematite reaction chain-I. Acquisition of chemical remanent magnetization by maghemite, its magnetic properties and thermal stability

Gendler, T. S.; Щербаков, В. П.; Dekkers, Mark J.; Gapeev, A. K.; Грибов, С. К.; McClelland, E.

doi:10.1111/j.1365-246x.2005.02550.x

Cited by 85 publications

(76 citation statements)

References 67 publications

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“…Moreover, the only direct Thellier experiments with TCRM and TRM that have been published in the literature and performed on SD maghemite grains precipitated in lepidocrocite grains showed a drastic non-similarity of the AraiNagata diagrams of these two remanences (Gendler et al, 2005). Thus, we conclude that the strong similarity of the NRM-TRM plots and the good quality of the Arai-Nagata …”

Section: Kafan Sectionmentioning

confidence: 74%

Rock magnetic and paleointensity results from Mesozoic baked contacts of Armenia

et al. 2009

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Samples were obtained from three baked contacts and one lava flow along the upper Turonian-lower Coniacian Tovuz section, two baked contacts along the upper Coniacian-lower Santonian Paravakar section in the northern part of Armenia, and three baked contacts along the Titonian-Valanginian Kafan section in southern Armenia. A total of 130 samples were studied. Updated mean paleomagnetic poles were calculated for the Upper Cretaceous Tovuz-Paravakar sections (65.6• N, 162.2 • E, A 95 = 4.3, paleolatitude = 27.0 ± 3.4• ) and the Upper JurassicLower Cretaceous Kafan section (61.7• N, 158.9• E, A 95 = 4.8• , paleolatitude = 24.7 ± 3.8 • ). Paleointensity determinations could be estimated from two of the upper Cretaceous and three of the Upper Jurassic-Lower Cretaceous baked contacts, corresponding to a 30% success rate. The mean virtual dipole moments obtained were low (1.7-5.5 × 10 22 A m 2 ), which is in agreement with data published by Solodovnikov (1981a, 1983) for the same sections (3.0-4.4 × 10 22 A m 2 ). Our results support the hypothesis of the Mesozoic Dipole Low, even though the overall data are widely dispersed.

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Section: Kafan Sectionmentioning

confidence: 74%

Rock magnetic and paleointensity results from Mesozoic baked contacts of Armenia

et al. 2009

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“…Özdemir and Dunlop (1993) studied the CRM accompanying the phase transformations lepidocrocite → maghemite → hematite in a field of 50 µT from 200 to 650 o C. They observed two CRM intensity peaks around 275 o C and 400 o C which were also detected by subsequent studies of Gendler et al (2005), where transformations lepidocrocite → maghemite and maghemite → hematite occur respectively, and CRM directions are always at a large angle to the applied field.…”

Section: Introductionmentioning

confidence: 87%

“…To further our understanding of CRM in red beds, the acquisition process of CRM in hematite has been simulated experimentally in the laboratory (Hedley, 1968;Bailey and Hale, 1981;Stokking and Tauxe, 1987,1990a, 1990bÖzdemir and Dunlop, 1993;Gendler et al, 2005). Two types of CRM are distinguished growth-CRM and alteration-CRM: the first involves growing of the magnetic minerals through the SP threshold; the second implies the alteration of an existing magnetic mineral to another magnetic mineral at a temperature below the magnetic ordering temperature.…”

Section: Introductionmentioning

confidence: 99%

Acquisition of chemical remanent magnetization during experimental ferrihydrite–hematite conversion in Earth-like magnetic field—implications for paleomagnetic studies of red beds

Jiang

Liu

Dekkers

et al. 2015

Earth and Planetary Science Letters

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Hematite-bearing red beds are renowned for their chemical remanent magnetization (CRM). If the CRM was acquired substantially later than the sediment was formed, this severely compromises paleomagnetic records. To improve our interpretation of the natural remanent magnetization, the intricacies of the CRM acquisition process must be understood. Here, we contribute to this issue by synthesizing hematite under controlled 'Earth-like' field conditions (< ~100 µT).CRM was imparted in 90 oriented samples with varying inclinations. The final magnetic remanence carrier is hematite with traces of ferrimagnetic ferrihydrite or maghemite. When the magnetic field intensity is > ~40 µT, CRM of hematite records the field direction faithfully. However, for growth field intensities < ~40 µT, the CRM direction may deviate considerably from that of the growth field. The CRM intensity normalized by the isothermal remanent magnetization (CRM/IRM @2.5 T ) increases linearly with the intensity of growth field, implying that CRM could potentially be useful for relative paleointensity studies. The hematite CRM has a distributed unblocking temperature spectrum from ~200 to ~650 °C while hematite with a depositional remanent magnetization (DRM) has a more confined spectrum from ~600 to 680 °C. Further, the CRM thermal demagnetization curves with their concave shape are notably different from their DRM counterparts which are convex. These differences together are suggested to be a potential discriminator of CRM from DRM carried by hematite in natural red beds, and of significance for the interpretation of paleomagnetic studies on red beds.

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“…Among these minerals, lepidocrocite (γ-FeOOH) has been less studied from a magnetism point of view than other iron-bearing minerals. It is commonly found in hydromorphic soils where there is seasonal alternation of reducing and oxidizing conditions, and has been shown to be a precursor of more magnetic phases such as maghemite or magnetite (eg., Fitzpatrick et al, 1985;Gehring and Hofmeister, 1994;Cornell and Schwertmann, 2003;Gendler et al, 2005;Till et al, 2014). Lepidocrocite is a ferric oxyhydroxide, orange in color, with an orthorhombic crystal structure (e.g., Ewing, 1935).…”

Section: Introductionmentioning

confidence: 99%

Constraining the Origins of the Magnetism of Lepidocrocite (γ-FeOOH): A Mössbauer and Magnetization Study

Guyodo¹,

Bonville

Till³

et al. 2016

Front. Earth Sci.

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Lepidocrocite, a widespread environmentally relevant iron oxyhydroxide, has been investigated for decades using 57 Fe Mössbauer spectroscopy and magnetic measurements. However, a coherent and comprehensive interpretation of all the data is still lacking due to seemingly contradictory interpretations. On one hand, temperature dependence of magnetic susceptibility and Mössbauer spectra resemble those of superparamagnetic nanoparticles with diameters less than 10 nm even though physically particles are lath-shaped with lengths on the order of 100-300 nm. On the other hand, in-field Mössbauer spectra show that lepidocrocite is an antiferromagnet and becomes paramagnetic above 50-70 K, a temperature close to the blocking temperature deduced from susceptibility data. The present study investigates a well-characterized synthetic sample of lepidocrocite, includes modeling of Mössbauer spectra and dc and ac magnetization data, and proposes a solution to this paradox. The new data are coherent with the presence of two entities in lepidocrocite: a bulk antiferromagnetic matrix and sparse ferrimagnetic nanosized inclusions (d = 3.4 nm), akin to maghemite, embedded within. The presence of nanosized ferrimagnetic inclusions is confirmed for the first time by Mössbauer spectroscopy.

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The lepidocrocite-maghemite-haematite reaction chain-I. Acquisition of chemical remanent magnetization by maghemite, its magnetic properties and thermal stability

Cited by 85 publications

References 67 publications

Rock magnetic and paleointensity results from Mesozoic baked contacts of Armenia

Rock magnetic and paleointensity results from Mesozoic baked contacts of Armenia

Acquisition of chemical remanent magnetization during experimental ferrihydrite–hematite conversion in Earth-like magnetic field—implications for paleomagnetic studies of red beds

Constraining the Origins of the Magnetism of Lepidocrocite (γ-FeOOH): A Mössbauer and Magnetization Study

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