High-Latitude Paleomagnetic Poles from Middle Jurassic Plutons and Moat Volcanics in New England and the Controversy Regarding Jurassic Apparent Polar Wander for North America

A paleomagnetic study of Middle Jurassic plutonic and volcanic rocks in New England (White Mountains Magma Series) yields high-latitude pole positions for North America. High unblocking temperature, moderate to high coercivity magnetizations of normal polarity have been isolated in three plutons (Wh...

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Bibliographic Details
Main Authors: Van Fossen, Mickey C., Kent, Dennis V.
Format: Text
Language:unknown
Published: Columbia University 1990
Subjects:
Geophysics
East Antarctica
Tilting
Conway
Corral
Antarc*
Antarctica
Online Access:https://dx.doi.org/10.7916/d8sj1w52
https://academiccommons.columbia.edu/doi/10.7916/D8SJ1W52
id ftdatacite:10.7916/d8sj1w52
record_format openpolar
spelling ftdatacite:10.7916/d8sj1w52 2023-05-15T13:50:30+02:00 High-Latitude Paleomagnetic Poles from Middle Jurassic Plutons and Moat Volcanics in New England and the Controversy Regarding Jurassic Apparent Polar Wander for North America Van Fossen, Mickey C. Kent, Dennis V. 1990 https://dx.doi.org/10.7916/d8sj1w52 https://academiccommons.columbia.edu/doi/10.7916/D8SJ1W52 unknown Columbia University Geophysics Text Articles article-journal ScholarlyArticle 1990 ftdatacite https://doi.org/10.7916/d8sj1w52 2021-11-05T12:55:41Z A paleomagnetic study of Middle Jurassic plutonic and volcanic rocks in New England (White Mountains Magma Series) yields high-latitude pole positions for North America. High unblocking temperature, moderate to high coercivity magnetizations of normal polarity have been isolated in three plutons (White Mountains batholith, Mount Monadnock, and the Belknap Mountains; mean age ~169 Ma), but the mean pole (88.4°N, 82.1°E, A_95 = 6.1°) is not distinguishable from the geographic axis and therefore the hypothesis that the plutons have been contaminated by recent field overprints can not be rejected. However, a dual polarity, high unblocking temperature, and high coercivity magnetization isolated from the Moat volcanics (169 Ma, Rb-Sr age) was apparently acquired soon after caldera collapse and tilting, at about the time of intrusion and cooling of the Conway granite (reported ages K-Ar biotite, 168 Ma; zircon fission track, 163 Ma). The Moat volcanics pole position (78.7°N, 90.3°E, dp = 7.1°, dm = 10.2°) calculated using the mean magnetization direction of reversed polarity (the Cr component) falls at high latitude but is distinguishable from the spin axis. Moreover, published Middle Jurassic paleomagnetic poles from Gondwana (Africa, Australia, and East Antarctica) transferred to the North American reference frame also suggest a high-latitude Middle Jurassic pole position for North America, in agreement with the Moat volcanics pole. The new evidence for a Middle Jurassic loop to high latitudes in the North American apparent polar wander path conflicts by 15°-20° with some key published Jurassic reference poles (e.g., the Newark Trend N2 and the Corral Canyon poles) used to constrain current paleomagnetic Euler pole (PEP) apparent polar wander paths for the Jurassic. We suggest that a plausible explanation for the discrepancy is that the N2 and Corral Canyon magnetizations are in fact secondary and were acquired after tilting. The hypothesis that the North American apparent polar wander path ventured to high latitude in the Middle Jurassic requires further testing, however the results of this study already suggest that the path may be more complicated than that proposed by recently published PEP studies. Text Antarc* Antarctica East Antarctica DataCite Metadata Store (German National Library of Science and Technology) East Antarctica Tilting ENVELOPE(-54.065,-54.065,49.700,49.700) Conway ENVELOPE(-61.422,-61.422,-62.841,-62.841) Corral ENVELOPE(-62.950,-62.950,-64.900,-64.900)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic Geophysics
spellingShingle Geophysics
Van Fossen, Mickey C.
Kent, Dennis V.
High-Latitude Paleomagnetic Poles from Middle Jurassic Plutons and Moat Volcanics in New England and the Controversy Regarding Jurassic Apparent Polar Wander for North America
topic_facet Geophysics
description A paleomagnetic study of Middle Jurassic plutonic and volcanic rocks in New England (White Mountains Magma Series) yields high-latitude pole positions for North America. High unblocking temperature, moderate to high coercivity magnetizations of normal polarity have been isolated in three plutons (White Mountains batholith, Mount Monadnock, and the Belknap Mountains; mean age ~169 Ma), but the mean pole (88.4°N, 82.1°E, A_95 = 6.1°) is not distinguishable from the geographic axis and therefore the hypothesis that the plutons have been contaminated by recent field overprints can not be rejected. However, a dual polarity, high unblocking temperature, and high coercivity magnetization isolated from the Moat volcanics (169 Ma, Rb-Sr age) was apparently acquired soon after caldera collapse and tilting, at about the time of intrusion and cooling of the Conway granite (reported ages K-Ar biotite, 168 Ma; zircon fission track, 163 Ma). The Moat volcanics pole position (78.7°N, 90.3°E, dp = 7.1°, dm = 10.2°) calculated using the mean magnetization direction of reversed polarity (the Cr component) falls at high latitude but is distinguishable from the spin axis. Moreover, published Middle Jurassic paleomagnetic poles from Gondwana (Africa, Australia, and East Antarctica) transferred to the North American reference frame also suggest a high-latitude Middle Jurassic pole position for North America, in agreement with the Moat volcanics pole. The new evidence for a Middle Jurassic loop to high latitudes in the North American apparent polar wander path conflicts by 15°-20° with some key published Jurassic reference poles (e.g., the Newark Trend N2 and the Corral Canyon poles) used to constrain current paleomagnetic Euler pole (PEP) apparent polar wander paths for the Jurassic. We suggest that a plausible explanation for the discrepancy is that the N2 and Corral Canyon magnetizations are in fact secondary and were acquired after tilting. The hypothesis that the North American apparent polar wander path ventured to high latitude in the Middle Jurassic requires further testing, however the results of this study already suggest that the path may be more complicated than that proposed by recently published PEP studies.
format Text
author Van Fossen, Mickey C.
Kent, Dennis V.
author_facet Van Fossen, Mickey C.
Kent, Dennis V.
author_sort Van Fossen, Mickey C.
title High-Latitude Paleomagnetic Poles from Middle Jurassic Plutons and Moat Volcanics in New England and the Controversy Regarding Jurassic Apparent Polar Wander for North America
title_short High-Latitude Paleomagnetic Poles from Middle Jurassic Plutons and Moat Volcanics in New England and the Controversy Regarding Jurassic Apparent Polar Wander for North America
title_full High-Latitude Paleomagnetic Poles from Middle Jurassic Plutons and Moat Volcanics in New England and the Controversy Regarding Jurassic Apparent Polar Wander for North America
title_fullStr High-Latitude Paleomagnetic Poles from Middle Jurassic Plutons and Moat Volcanics in New England and the Controversy Regarding Jurassic Apparent Polar Wander for North America
title_full_unstemmed High-Latitude Paleomagnetic Poles from Middle Jurassic Plutons and Moat Volcanics in New England and the Controversy Regarding Jurassic Apparent Polar Wander for North America
title_sort high-latitude paleomagnetic poles from middle jurassic plutons and moat volcanics in new england and the controversy regarding jurassic apparent polar wander for north america
publisher Columbia University
publishDate 1990
url https://dx.doi.org/10.7916/d8sj1w52
https://academiccommons.columbia.edu/doi/10.7916/D8SJ1W52
long_lat ENVELOPE(-54.065,-54.065,49.700,49.700)
ENVELOPE(-61.422,-61.422,-62.841,-62.841)
ENVELOPE(-62.950,-62.950,-64.900,-64.900)
geographic East Antarctica
Tilting
Conway
Corral
geographic_facet East Antarctica
Tilting
Conway
Corral
genre Antarc*
Antarctica
East Antarctica
genre_facet Antarc*
Antarctica
East Antarctica
op_doi https://doi.org/10.7916/d8sj1w52
_version_ 1766253544864743424

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