Field‐impressed anisotropies of magnetic susceptibility and remanence in minerals

Potter, David K.; Stephenson, A.

doi:10.1029/jb095ib10p15573

Cited by 64 publications

(74 citation statements)

References 24 publications

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“…Many specimens had a K too weak for anisotropy to be reliably determined; we rejected specimens with significantly more than 1% rms error (defined as the root-mean-square of the differences between rep_•.at measurements of the same matrix element divided by K). Results for the remaining 20 specimens are given in Table 4, Susceptibility anisotropy was measured after ARM anisotropy and hence may be affected by field-impressed susceptibility anisotropy [Potter and Stephenson, 1990]. Any such effect was evidently not great enough to change the basic shape of the susceptibility ellipsoid, which is strongly foliated in the bedding plane like the ARM ellipsoid.…”

Section: Susceptibility Hnisotropymentioning

confidence: 99%

Can remanence anisotropy detect paleomagnetic inclination shallowing due to compaction? A case study using Cretaceous deep‐sea limestones

Hodych¹,

Bijaksana²

1993

J. Geophys. Res.

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Section: Susceptibility Hnisotropymentioning

confidence: 99%

Can remanence anisotropy detect paleomagnetic inclination shallowing due to compaction? A case study using Cretaceous deep‐sea limestones

Hodych¹,

Bijaksana²

1993

J. Geophys. Res.

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“…Observations of k or AMS are truly unique and universal only where RBM are absent or of low abundance and dispersed. Furthermore, exposure to high fields changes ''k 0 '' and AMS noticeably for rocks rich in certain multidomainal accessory RBM (B1% by volume) (POTTER and STEPHENSON, 1990), especially magnetite and pyrrhotite. For reproducible determination of low-field susceptibility in specimens rich in multidomain, low coercivity RBM, it may be advisable to demagnetize carefully first, by a nondestructive but isotropic technique.…”

Section: Susceptibility Measurement Conditions Especially Field-depementioning

confidence: 99%

“…For reproducible determination of low-field susceptibility in specimens rich in multidomain, low coercivity RBM, it may be advisable to demagnetize carefully first, by a nondestructive but isotropic technique. Low-temperature demagnetization is preferable since thermal demagnetization may cause mineralogical change and static three-axis AF demagnetization may reset ''k 0 '' and AMS (POTTER and STEPHENSON, 1990). Tumbling AF demagnetization can never expose every axis through the specimen to every demagnetizing field value and thus risks imposing some anisotropy.…”

Section: Susceptibility Measurement Conditions Especially Field-depementioning

confidence: 99%

“…1a). To measure k 0 with sufficient precision and reproducibility for anisotropy studies (AMS) any exposure to high fields must be avoided (e.g., POTTER and STEPHENSON, 1990). First the specimen should be demagnetized in a nondestructive manner; low-temperature demagnetization being the most cautious technique, although neither universally nor completely successful.…”

Section: Figurementioning

confidence: 99%

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Induced Magnetization of Magnetite-titanomagnetite in Alternating Fields Ranging from 400 A/m to 80,000 A/m; Low-field Susceptibility (100 – 400 A/m) and Beyond

Borradaile

Stupavsky²,

Metsaranta

2008

Pure appl. geophys.

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For remanence-bearing minerals (RBM) such as magnetite-titanomagnetite, susceptibility to induced magnetism (M) measured in alternating fields (H AC ) is field-dependent. However, for fields B 400 A/m, measured in an AC induction coil instrument (at 19,100 Hz), susceptibility k 0 = M/H AC is sufficiently linear to provide a reproducible rock (or mineral) magnetic characteristic and its anisotropy may be related to arrangements of minerals in rock, or for single mineral grains to their crystalline or shape anisotropy. For any remanence-bearing mineral at higher fields k HF (¼ M/H AC ) is not constant and the term susceptibility is not normally used. This study bridges the responses between traditional low-field susceptibility measurements and those due to high applied fields, for example when studying hysteresis or saturation magnetization of RBM. Where |k HF | is measured in alternating fields that peak significantly above 400 A/m the M(H AC ) relation is forced to follow a hysteresis loop in which |k HF | > k 0 for small |H AC | and where |k HF | decreases to zero for very large fields that achieve saturation magnetization. Hysteresis nonlinearity is due to remanence acquired with one field direction requiring a reverse field for its cancellation. We investigate the transition from initial, traditional ''lowfield'' susceptibility (k 0 ) measurements at 60 A/m, through 24 different fields from 400 A/m to 40,000 A/m (for very high k 0 to 80,000 A/m). This reveals M(H AC ) dependence beyond from conventional k 0 through the range of hysteresis behavior in fields equal to and exceeding that required to achieve saturation magnetization (M S ). We show k HF increases with peak H AC until the peak field is slightly less than saturation magnetization in natural rock samples rich in magnetite (TM 0 ¼ Fe 3 O 4 ) and TM 60 (Fe 2.4 Ti 0.6 O 4 ). All sample suites predominantly contain multidomain grains with subordinate pseudo-single domain and single-domain grains. k/k 0 increases by B 5% for fields up to 2 kA/m. Above 4 kA/m k/ k 0 increases steeply and peaks, usually between 24 kA/m and 30 kA/m where all grains magnetic moments are activated by H AC since this exceeds the coercive force of most grains. For higher peak H AC , k/k 0 declines sharply as increased H AC values more effectively flip M with each field-direction switch, leading to the low gradient at distal portions of the hysteresis loop. For M 0 -TM 60 bearing rocks, susceptibility peaks for fields *12 kA/m and for magnetite rich rocks up to 24 kA/m. These values are approximately 10% of saturation magnetizations (M S ) reported for the pure minerals from hysteresis DC field measurements. Both the field at peak k/k 0 and the peak k/k 0 value appear to be controlled by the dominant domain structure; multidomain behavior has larger k/k 0 peaks at lower H AC . Stacked k/k 0 versus H AC curves for each sample suite (n = 12 to n = 39) were successfully characterized at the 95% level by a polynomial fit that requires the cubic form k/k 0 = a + bH + cH 2 + dH 3 . Thu...

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“…For the majority of the samples (39) the AMS measurements were conducted before demagnetization, but some (25) were shipboard samples that were demagnetized by AF cleaning on the drill ship before AMS fabric was determined. The sequence of measurement is important because the application of a static alternating field can impress an anisotropy (Potter and Stephenson, 1990), an effect we have been able to reproduce in some of these samples. For this reason we have excluded the shipboard samples from our discussion of the AMS fabrics.…”

Section: Magnetic Fabricsmentioning

confidence: 99%

Structures and Magnetic Fabrics from the Lower Sheeted Dike Complex of Hole 504B Reoriented Using Stable Magnetic Remanence

Allerton¹,

McNeill²,

Stokking³

et al. 1995

Proceedings of the Ocean Drilling Program, 137/140 Scientific Results

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Structural measurements from core from the sheeted dike complex recovered during Ocean Drilling Program Legs 137 and 140 to Hole 504B have been reoriented using the paleomagnetic stable declination. Two dike margins observed in the core restore to an approximately east-west strike, and a steep dip to the north, parallel to the orientation of the Costa Rica Rift. Veins can be divided into two sets. The veins of one set are perpendicular to the dike margins, with a range of dips; these veins are interpreted as cooling fractures, formed by the thermal contraction of the dikes. The veins of the second set are parallel to the dikes, dipping steeply and striking approximately east-west. We suggest that these were formed by hot brines with high fluid pressures generated during dike intrusion by contact of fluids in the host rock with molten lava. Unmineralized fractures in the core probably result from anelastic stress-relaxation when the core is brought to the surface. Two dominant orientations occur: subhorizontal discing fractures, and subvertical fractures, which are subparallel, with a mean strike of 131°, approximately parallel to the minimum horizontal in-situ stress estimated for borehole breakout studies.The samples have a weak anisotropy of magnetic susceptibility, with a distribution of maximum axes with a dominantly shallow inclination. The origin of this fabric is not clear. In geographic coordinates the maximum axis corresponds closely to the present maximum horizontal stress direction, which suggests that the fabric may result from internal stresses. In sample coordinates the maximum fabric corresponds to the long axis of the core. This suggests that the fabric may be related to the sample, rather than being an inherent petrologic property.

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Field‐impressed anisotropies of magnetic susceptibility and remanence in minerals

Cited by 64 publications

References 24 publications

Can remanence anisotropy detect paleomagnetic inclination shallowing due to compaction? A case study using Cretaceous deep‐sea limestones

Can remanence anisotropy detect paleomagnetic inclination shallowing due to compaction? A case study using Cretaceous deep‐sea limestones

Induced Magnetization of Magnetite-titanomagnetite in Alternating Fields Ranging from 400 A/m to 80,000 A/m; Low-field Susceptibility (100 – 400 A/m) and Beyond

Structures and Magnetic Fabrics from the Lower Sheeted Dike Complex of Hole 504B Reoriented Using Stable Magnetic Remanence

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