Page 5 - i1052-5173-26-12
P. 5
different continents and centered on ca. 145 Ma (Kent and Irving, 2. The ca. 145 Ma combined Bumbeni-Swartruggens paleopole
2010). The mean location of these three poles plots as the apex or from South Africa, comprised of the Bumbeni syenite
cusp of a novel APW path when reconstructed to common coor- complex dated with Ar/Ar at 145.8 ± 1.3 Ma, which yielded
dinates using standard relative plate reconstructions. The APW bipolar paleomagnetic results from four sites, and the
path was constructed from published paleomagnetic poles from kimberlite fissures at Swartruggens dated with K-Ar and Ar/
well-dated magmatic units and only those sedimentary units Ar to a mean of 142 ± 4 Ma, which also yielded bipolar paleo-
corrected for inclination flattening (Tauxe and Kent, 2004; Kent magnetic results from two sites (Main and Male kimberlites;
and Tauxe, 2005). The poles range in age from 230 to 50 Ma Hargraves et al., 1997, and references therein).
(Triassic to Eocene) from all the major continents that could be
closely linked by plate circuits (see Fig. 4 in Kent and Irving, 3. The Hinlopenstretet paleopole from Svalbard, based on high-
2010). The resulting global composite APW path shows the pres- temperature magnetic component directions from 17 sites
ence of a previously undetected yet major polar shift of ~30° sepa- sampled in dikes dated with K-Ar to a mean age of 144 ± 5 Ma
rating the 160 Ma (Oxfordian, Late Jurassic) mean paleopole from (Halvorsen, 1989).
the mean cusp paleopole at 145 Ma, close in age to the Jurassic-
Cretaceous boundary. The Bumbeni-Swartruggens and Hinlopenstretet paleopoles,
when transferred into North American coordinates using rotation
Whether the 1–2°/m.y. of Jurassic polar shift represents an parameters to account for seafloor spreading in the Atlantic, fall
episode of fast whole mantle rotation (TPW) or only rotation at only 6° and 8°, respectively, from the cratonic Ithaca paleopole;
of the reconstructed continental lithosphere (APW), the main this congruence of results from three continents allows erecting a
continents in either case rotated in unison clockwise by up to mean paleopole at ca. 145 Ma with a 95% confidence circle (A95)
~30° about a Euler pole centered on the equator (Fig. 1; Kent et al., of 9° (Kent and Irving, 2010).
2015). As a result, Arabia drifted southward from straddling the
ITCZ at ca. 160 Ma to plunging at up to 1–2°/m.y. (up to ~20 cm/yr) The position of the ca. 145 Ma apex paleopole is confirmed by
into the tropical arid belt of the southern hemisphere by 145 Ma. entirely independent data from magneto-biostratigraphically
The main continents then rotated in unison anticlockwise about dated sections from Adria—the African promontory. These data
virtually the same Euler pole so that Arabia drifted northward have been successfully correlated to the marine magnetic anomaly
back across the ITCZ and into the boreal arid belt by 120 Ma. M-sequence and corrected for sedimentary inclination shallowing
Such a rapid polar shift and the backtrack at the 145 Ma cusp are (Muttoni et al., 2013). Two mean paleomagnetic poles for Adria-
not precluded either by any speed limit on plates (Meert et al., Africa are of particular interest for our discussion: a mean paleo-
1993) coupled with their negligible momentum (Forsyth and pole based on three stratigraphic sections straddling magnetic
Uyeda, 1975) nor by models of whole-mantle motions for TPW polarity chron CM22 at 151 ± 1 Ma in the Early Tithonian, and a
(Tsai and Stevenson, 2007; Greff-Lefftz and Besse, 2014). mean paleopole at 145 ± 2 Ma in the mid-Tithonian–Berriasian
(across the Jurassic-Cretaceous boundary) based on six sections
The critical 145 Ma apex paleopole of Kent and Irving (2010) is altogether from polarity chron CM17 to CM21 (Muttoni et al.,
based on an average of three individual entries from radiometri- 2013). These two paleopoles at ca. 151 and ca. 145 Ma lie at only
cally dated igneous units: 1° and 7°, respectively, from the ca. 145 Ma paleopole of Kent and
1. The Ithaca kimberlite paleopole from New York State in Irving (2010) rotated into African coordinates (Muttoni et al.,
2013). Finally, a mean kimberlite paleopole from Ontario, Canada,
North America, based on high-temperature magnetic dated with state-of-the-art U/Pb on perovskite to 156 ± 1.6 Ma,
component directions bearing dual (normal and reverse) neatly plots in the middle of the Jurassic polar shift and provides
polarity from seven sites sampled in dikes intruding flat- additional independent support for it (Kent et al., 2015).
lying Devonian platform carbonates, giving a positive baked
contact test and with a geometry that precludes significant Acknowledging the limitations of our small subset of nonethe-
post-emplacement tectonic disturbances (Van Fossen and less well-dated and inclination flattening-free Late Jurassic paleo-
Kent, 1993); the Ithaca kimberlites are now provided with a poles from stable regions of different plates (North America,
U/Pb perovskite date of 146.4 ± 1.4 Ma (Kent et al., 2015). Europe, Africa), the overall coherent progression they depict once
restored to a common reference frame, confirmed by magneto-
160 Ma arid GoM 120 Ma Figure 1. Paleocontinental reconstructions bracketing GSA TODAY | www.geosociety.org/gsatoday
145 Ma the Jurassic polar shift: in left panel, reconstructions
arid 145 Ma Ghawar ITCZ E at 160 Ma (light gray shading) and 145 Ma (dark gray
arid Neuqén Ghawar shading); in right panel, reconstructions at 145 Ma
GoM (light gray shading; same as in left panel) and 120 Ma
ITCZ (dark gray shading). The Euler pole (E) for rotating the
continental assemblage clockwise from 160 to 145 Ma
E and counterclockwise from 145 to 120 Ma is located
arid on the equator in the vicinity of the Bight of Benin of
western Africa. The stars connected by arrows
Neuqén indicate the sites discussed in the text: Ghawar in
Saudi Arabia, Neuqén in Argentina, and the Gulf of
Mexico (GoM). Green latitudinal belts represent the
Intertropical Convergence Zone (ITCZ) within ±5°
equator and the temperate humid belts, whereas the
arid belts encompass the tropics up to ±30° latitude
(modified from Kent et al., 2015).
5
