Paleomagnetism and paleothermometry of the Sydney Basin 2. Origin of anomalously high unblocking temperatures

Paleomagnetism and paleothermometry of the Sydney Basin 2. Origin of anomalously high unblocking temperatures

The Milton Monzonite of southeastern Australia was thermoviscously remagnetized as a result of Cretaceous burial and uplift. Thermal demagnetization separates the low unblocking temperature (LT) overprint from the high unblocking temperature (HT) primary remanence, with a relatively sharp junction b...

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Bibliographic Details
Published in:Journal of Geophysical Research: Solid Earth Vol. 102; no. B12; pp. 27285 - 27295
Main Authors: Dunlop, D. J., Özdemir, Ö., Schmidt, P. W.
Format: Journal Article
Language:English
Published: Washington, DC Blackwell Publishing Ltd 10-12-1997
American Geophysical Union
Subjects:
Earth sciences
Earth, ocean, space
Exact sciences and technology
Geophysics: general, magnetic, electric and thermic methods and properties
Internal geophysics
Australia
Sydney Basin
New South Wales
Mesozoic
Curie point
paleotemperature
Australasia
viscous remanent magnetization
igneous rocks
Cretaceous
anomalies
magnetic domains
monzonites
remagnetization
corrections
thermal demagnetization
closure temperature
uplifts
paleomagnetism
plutonic rocks
Upper Cretaceous
Phanerozoic
remanent magnetization
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Summary:The Milton Monzonite of southeastern Australia was thermoviscously remagnetized as a result of Cretaceous burial and uplift. Thermal demagnetization separates the low unblocking temperature (LT) overprint from the high unblocking temperature (HT) primary remanence, with a relatively sharp junction between LT and HT components in vector projections. For single‐domain grains, the junction temperature TL between two such vectors corresponds to the maximum blocking temperature Tr reactivated in nature, apart from a correction for the difference between natural and laboratory timescales. However, measured TL values are distributed over an implausibly wide range (>250°C) for burial remagnetization of an untilted intrusion like the Milton Monzonite. Furthermore, many TL values are anomalously high compared to the predictions of single‐domain theory. Multidomain grains are the cause of these anomalies. Samples pretreated before thermal demagnetization by zero‐field cycling to liquid nitrogen temperature, so as to erase multidomain remanence and isolate single‐domain remanence, do have the theoretically expected TL values. In these samples, realistic remagnetization time and temperature (tr, Tr) conditions in nature are predicted using the t‐T contours of Pullaiah et al. [1975]. The anomalously high TL values before low‐temperature treatment are due to multidomain grains, which carry ≥50% of the LT overprint. The LT thermal demagnetization curve in samples dominated by multidomain grains is quasi‐exponential in shape with a high‐temperature tail extending almost to the Curie point, as predicted by multidomain theory. These high LT unblocking temperatures, which are much greater than plausible remagnetization temperatures reached in nature, overlap and mask the lower part of the HT unblocking temperature spectrum, driving up TL values and leading to inflated estimates of Tr. Although multidomain remanence is a sufficient explanation of anomalously high unblocking temperatures of thermoviscous overprints in the Milton Monzonite, chemical overprinting may be a factor in other lithologies and tectonic settings.
Bibliography:ArticleID:97JB02478
istex:8943D898280BF23A5ED5B9F2731B5F61F629A3D2
ark:/67375/WNG-HNWGT1NW-W
ISSN:0148-0227
2156-2202
DOI:10.1029/97JB02478