TY - JOUR
T1 - The Mutare–Fingeren dyke swarm
T2 - the enigma of the Kalahari Craton’s exit from supercontinent Rodinia
AU - Gumsley, Ashley P.
AU - de Kock, Michiel
AU - Ernst, Richard
AU - Gumsley, Anna
AU - Hanson, Richard
AU - Kamo, Sandra
AU - Knoper, Michael
AU - Lewandowski, Marek
AU - Luks, Bartłomiej
AU - Mamuse, Antony
AU - Söderlund, Ulf
N1 - Publisher Copyright:
© 2023 The Author(s).
PY - 2024
Y1 - 2024
N2 - The Rodinia supercontinent broke apart during the Neoproterozoic. Rodinia break-up is associated with widespread intraplate magmatism on many cratons, including the c. 720–719 Ma Franklin large igneous province (LIP) of Laurentia. Coeval magmatism has also been identified recently in Siberia and South China. This extensive magmatism terminates ∼1 myr before the onset of the Sturtian Snowball Earth. However, LIP-scale magmatism and global glaciation are probably related. U–Pb isotope dilution–thermal ionization mass spectrometry (ID-TIMS) baddeleyite dating herein identifies remnants of a new c. 724–712 Ma LIP on the eastern Kalahari Craton in southern Africa and East Antarctica: the combined Mutare–Fingeren Dyke Swarm. This dyke swarm occurs in northeastern Zimbabwe (Mutare Dyke Swarm) and western Dronning Maud Land (Fin-geren Dyke Swarm). It has incompatible element-enriched mid-ocean ridge basalt-like geochemistry, suggest-ing an asthenospheric mantle source for the LIP. The Mutare–Fingeren LIP probably formed during rifting. This rifting would have occurred almost ∼100 myr earlier than previous estimates in eastern Kalahari. The placement of Kalahari against southeastern Laurentia in Rodinia is also questioned. Proposed alternatives, invoking link-ing terranes between Kalahari and southwestern Laurentia or close to northwestern Laurentia, also present chal-lenges with no discernible resolution. Nevertheless, LIP-scale magmatism being responsible for the Sturtian Snowball Earth significantly increases.
AB - The Rodinia supercontinent broke apart during the Neoproterozoic. Rodinia break-up is associated with widespread intraplate magmatism on many cratons, including the c. 720–719 Ma Franklin large igneous province (LIP) of Laurentia. Coeval magmatism has also been identified recently in Siberia and South China. This extensive magmatism terminates ∼1 myr before the onset of the Sturtian Snowball Earth. However, LIP-scale magmatism and global glaciation are probably related. U–Pb isotope dilution–thermal ionization mass spectrometry (ID-TIMS) baddeleyite dating herein identifies remnants of a new c. 724–712 Ma LIP on the eastern Kalahari Craton in southern Africa and East Antarctica: the combined Mutare–Fingeren Dyke Swarm. This dyke swarm occurs in northeastern Zimbabwe (Mutare Dyke Swarm) and western Dronning Maud Land (Fin-geren Dyke Swarm). It has incompatible element-enriched mid-ocean ridge basalt-like geochemistry, suggest-ing an asthenospheric mantle source for the LIP. The Mutare–Fingeren LIP probably formed during rifting. This rifting would have occurred almost ∼100 myr earlier than previous estimates in eastern Kalahari. The placement of Kalahari against southeastern Laurentia in Rodinia is also questioned. Proposed alternatives, invoking link-ing terranes between Kalahari and southwestern Laurentia or close to northwestern Laurentia, also present chal-lenges with no discernible resolution. Nevertheless, LIP-scale magmatism being responsible for the Sturtian Snowball Earth significantly increases.
UR - http://www.scopus.com/inward/record.url?scp=85177566674&partnerID=8YFLogxK
U2 - 10.1144/SP537-2022-206
DO - 10.1144/SP537-2022-206
M3 - Article
AN - SCOPUS:85177566674
SN - 0305-8719
VL - 537
SP - 359
EP - 380
JO - Geological Society Special Publication
JF - Geological Society Special Publication
ER -